Chemiluminescence measurement apparatus

ABSTRACT

Disclosed is a chemiluminescence measurement apparatus that includes: a support member configured to support a cartridge for measuring a test substance contained in a specimen by chemiluminescence measurement; a motor configured to rotate the support member so as to rotate the cartridge such that a process required for the chemiluminescence measurement proceeds in the cartridge; and a light receiver configured to receive light generated by chemiluminescence in the cartridge that is supported by the support member rotated by the motor. The cartridge supported by the support member and a light receiving surface of the light receiver are disposed inside a dark space surrounded by a light-shielding portion, and the motor is disposed outside the dark space.

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims priority from prior Japanese Patent Application Nos. 2016-130101, filed on Jun. 30, 2016, and 2016-179031, filed on Sep. 13, 2016, each entitled “CHEMILUMINESCENCE MEASUREMENT APPARATUS”, the entire contents of which are incorporated herein by reference.

FIELD OF THE INVENTION

The present invention relates to a chemiluminescence measurement apparatus for measuring a test substance by using a cartridge for chemiluminescence measurement.

BACKGROUND

US Patent Application Publication No. 2013/0164175 (hereinafter, referred to as Patent Literature 1) discloses an analyzer for analyzing a specimen such as blood, saliva, or urine by using a disk 610, as shown in FIG. 28. The analyzer includes: a rotation device 620 for rotating the disk 610 in order to cause the specimen and a reagent to react with each other in the disk 610; a light emitter 640 for irradiating, with light, a detection zone 630 including a chamber; and a light detector 650 for receiving light that has transmitted through the detection zone 630.

In the analyzer disclosed in Patent Literature 1, a camera is used as the light detector 650, and an image of the detection zone 630 that is irradiated with light by the light emitter 640 is taken by the camera, whereby a reaction result in the detection zone 630 is obtained according to the density of a color or change of a color in the taken image. All of the disk 610, the rotation device 620, the light emitter 640, and the light detector 650 are stored inside a box-shaped main body 660.

In a device such as the analyzer disclosed in Patent Literature 1 in which a cartridge is rotated in the box-shaped main body for reduction in size, in a case where chemiluminescence measurement for measuring low light generated in the cartridge by chemiluminescence is performed, the light needs to be detected at photon counting level, and, therefore, light-shielding needs to be sufficient so as to prevent light from leaking from the outside into the space in which the cartridge is stored. In this case, since the space in which the cartridge is stored is a closed space, it is difficult to dissipate heat to the outside. In a case where light is generated in the cartridge by chemiluminescence, if the temperature in the space in which the cartridge is stored varies, a chemical reaction in the cartridge becomes unstable, resulting in accuracy for chemiluminescence measurement being reduced. Therefore, the temperature in the space in which the cartridge is stored is preferably maintained at a predetermined temperature.

SUMMARY OF THE INVENTION

The scope of the present invention is defined solely by the appended claims, and is not affected to any degree by the statements within this summary.

A chemiluminescence measurement apparatus according to a main aspect of the present invention is a chemiluminescence measurement apparatus that includes: a support member configured to support a cartridge for measuring a test substance contained in a specimen by chemiluminescence measurement; a motor configured to rotate the support member so as to rotate the cartridge such that a process required for the chemiluminescence measurement proceeds in the cartridge; and a light receiver configured to receive light generated by chemiluminescence in the cartridge that is supported by the support member rotated by the motor. The cartridge supported by the support member and a light receiving surface of the light receiver are disposed inside a dark space surrounded by a light-shielding portion, and the motor is disposed outside the dark space.

In the chemiluminescence measurement apparatus according to this mode, the chemiluminescence represents light generated by using energy caused by a chemical reaction, for example, represents light emitted when molecules excited into an excited state by chemical reaction, are returned from the excited state to a ground state. The chemiluminescence can be generated, for example, by reaction between an enzyme and a substrate, by application of electrochemical stimuli to a labeling substance, by an LOCI (luminescent oxygen channeling immunoassay), or according to bioluminescence. The chemiluminescence measurement refers to measurement of chemiluminescence. A process required for chemiluminescence measurement is a process required until the chemiluminescence is measured. The process required for chemiluminescence measurement includes a process for generating the chemiluminescence. Examples of the process for generating the chemiluminescence include: a process for causing a luminescent substrate and a catalyst to react with each other; a process for applying electrochemical stimuli to a labeling substance; a process for applying light to generate singlet oxygen, and oxidizing an olefin compound by the generated singlet oxygen according to the LOCI (luminescent oxygen channeling immunoassay); and a process for generating bioluminescence by luciferin/luciferase. The dark space is a space surrounded by the light-shielding portion. The dark space is not particularly limited, and may be a space having such darkness as to stably detect chemiluminescence. For example, the dark space is a space that is surrounded by the light-shielding portion such that the number of incident photons detected in the dark space is less than or equal to 10000/(mm²·sec.) in a state where chemiluminescence is not generated in the cartridge. The state where chemiluminescence is not generated in the cartridge is, for example, a state where the cartridge is not set, or a state where power supply of the apparatus is off. From the viewpoint of a test substance being detected with enhanced sensitivity, the dark space is a space surrounded by the light-shielding portion such that the number of incident photons detected in the dark space is preferably less than or equal to 1000/(mm²·sec.), and more preferably less than or equal to 100/(mm²·sec.) in a state where chemiluminescence is not generated in the cartridge.

A method according to another aspect of the present invention is a method for measuring a test substance by using a chemiluminescence measurement apparatus, and the method includes: rotating a cartridge disposed inside a dark space of the chemiluminescence measurement apparatus by using a motor disposed outside the dark space; causing a process required for measuring the test substance by chemiluminescence measurement to proceed in the cartridge; and receiving, by a light receiver disposed inside the dark space, light generated in the cartridge by chemiluminescence. The dark space is surrounded by a light-shielding portion.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a schematic diagram illustrating a structure of a chemiluminescence measurement apparatus according to an outline of Embodiment 1;

FIG. 1B is a schematic diagram illustrating a structure of a cartridge according to the outline of Embodiment 1;

FIG. 2A is a schematic diagram illustrating an external structure of an analyzer according to Embodiment 1;

FIG. 2B is a schematic diagram illustrating a structure of a cartridge according to Embodiment 1 as viewed from thereabove;

FIG. 3 illustrates structures of a mounting member, a magnet, a movement mechanism, a detector, and a housing unit according to Embodiment 1 as viewed from diagonally thereabove;

FIG. 4A illustrates the structures of the magnet and the movement mechanism according to Embodiment 1 as viewed from diagonally therebelow;

FIG. 4B is a schematic diagram illustrating the structure of the magnet according to Embodiment 1 as viewed from the side thereof;

FIG. 5A illustrates the structure of the detector according to Embodiment 1 as viewed from diagonally thereabove;

FIG. 5B illustrates a structure of a reflector according to Embodiment 1 as viewed from diagonally thereabove;

FIG. 5C is a schematic diagram illustrating a cross-section of the reflector according to Embodiment 1 along a YZ plane as viewed from the side thereof;

FIG. 6A illustrates the structure of the detector, according to Embodiment 1; which does not have a member and the reflector, as viewed from diagonally thereabove;

FIG. 6B is a schematic diagram illustrating a state where light generated from a chamber is received by a light detector, according to Embodiment 1, as viewed from the lateral side;

FIG. 7 illustrates a state where a motor, an elastic member, and a lid member are mounted to the housing unit, according to Embodiment 1, as viewed from diagonally therebelow;

FIG. 8 illustrates a structure of a body portion according to Embodiment 1 as viewed from diagonally thereabove and a structure of a lid portion according to Embodiment 1 as viewed from diagonally therebelow;

FIG. 9 is a schematic diagram illustrating the cross-section, of the analyzer, which is taken at the plane that is parallel to the YZ plane and that passes through a rotation axis, according to Embodiment 1, as viewed from the side thereof;

FIG. 10A is a schematic diagram illustrating a structure of a pressing portion according to Embodiment 1 as viewed from thereabove;

FIG. 10B is a schematic diagram illustrating a cross-section of the structure of the pressing portion according to Embodiment 1 as viewed from the side thereof;

FIG. 10C is a schematic diagram illustrating the cross-section of the structure of the pressing portion according to Embodiment 1 as viewed from the side thereof;

FIG. 11A is a schematic diagram illustrating a structure of a support member according to Embodiment 1 as viewed from thereabove;

FIG. 11B is a schematic diagram illustrating a structure of a support member according to modification of Embodiment 1 as viewed from thereabove;

FIG. 12A illustrates an internal structure of the body portion according to Embodiment 1 as viewed from therebelow;

FIG. 12B is a schematic diagram illustrating the internal structure of the body portion according to Embodiment 1 as viewed from the side thereof;

FIG. 13 is a block diagram illustrating a configuration of the analyzer according to Embodiment 1;

FIG. 14 is a flow chart showing an operation of the analyzer according to Embodiment 1;

FIG. 15 is a flow chart showing an operation of the analyzer in the case of a complex being transferred between chambers adjacent to each other, according to Embodiment 1;

FIG. 16A schematically illustrates a state transition in which a complex is transferred between chambers adjacent to each other, according to Embodiment 1;

FIG. 16B schematically illustrates a state transition in which the complex is transferred between the chambers adjacent to each other, according to Embodiment 1;

FIG. 16C schematically illustrates a state transition in which the complex is transferred between the chambers adjacent to each other, according to Embodiment 1;

FIG. 17A schematically illustrates a state transition in which the complex is transferred between the chambers adjacent to each other, according to Embodiment 1;

FIG. 17B schematically illustrates a state transition in which the complex is transferred between the chambers adjacent to each other, according to Embodiment 1;

FIG. 17C schematically illustrates a state transition in which the complex is transferred between the chambers adjacent to each other, according to Embodiment 1;

FIG. 18 illustrates relationship between variation in signal and variation in dark count value, which is obtained by verification as to whether or not light-shielding by a light-shielding portion is appropriate, according to Embodiment 1;

FIG. 19A illustrates a table that collectively indicates operation times of motors used in the analyzer, according to Embodiment 1;

FIG. 19B illustrates a graph indicating temperature change of the cartridge in each verification in the case of the motor being disposed in a dark space, according to Embodiment 1;

FIG. 20A illustrates a graph indicating temperature change of each component in the analyzer in verification as to the effect of a ventilator, according to Embodiment 1;

FIG. 20B illustrates a graph indicating temperature change of each component in the analyzer in the verification as to the effect of the ventilator, according to Embodiment 1;

FIG. 21A is a schematic diagram illustrating an external structure of an analyzer according to Embodiment 2;

FIG. 21B schematically illustrates structures of a support member and a cartridge, according to Embodiment 3, as viewed from thereabove;

FIG. 22A is a schematic diagram illustrating a structure in which a light receiver is disposed inside a dark space in a chemiluminescence measurement apparatus according to Embodiment 4;

FIG. 22B is a schematic diagram illustrating a structure in which a light receiving surface is disposed inside the dark space in the chemiluminescence measurement apparatus according to Embodiment 4;

FIG. 23A illustrates modification of the chemiluminescence measurement apparatus according to Embodiment 4 shown in FIG. 22A;

FIG. 23B illustrates modification of the chemiluminescence measurement apparatus according to Embodiment 4 shown in FIG. 22B;

FIG. 24A is a schematic diagram illustrating a structure of a cartridge according to Embodiment 5 as viewed from thereabove;

FIG. 24B is an enlarged schematic diagram illustrating a chamber of the cartridge according to Embodiment 5;

FIG. 24C is an enlarged schematic diagram illustrating the chamber of the cartridge according to Embodiment 5;

FIG. 24D is an enlarged schematic diagram illustrating a chamber of a cartridge according to a comparative example;

FIG. 24E is an enlarged schematic diagram illustrating a chamber of a cartridge according to a comparative example;

FIG. 25A is a schematic diagram illustrating a chamber according to modification of Embodiment 5;

FIG. 25B is a schematic diagram illustrating a chamber according to modification of Embodiment 5;

FIG. 25C is a schematic diagram illustrating a chamber according to modification of Embodiment 5;

FIG. 26A is a schematic diagram illustrating a structure of a cartridge according to Embodiment 6 as viewed from thereabove;

FIG. 26B is a schematic diagram illustrating a structure of a pressing portion according to Embodiment 6 as viewed from thereabove;

FIG. 27A is a schematic diagram illustrating a cross-section of the structure of the pressing portion according to Embodiment 6 as viewed from the side thereof;

FIG. 27B is a schematic diagram illustrating a cross-section of the structure of the pressing portion according to Embodiment 6 as viewed from the side thereof; and

FIG. 28 is a schematic diagram illustrating a structure of a related art.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiment 1

Outlines of a chemiluminescence measurement apparatus and a cartridge according to Embodiment 1 will be described with reference to FIG. 1A and FIG. 1B.

As shown in FIG. 1A, a chemiluminescence measurement apparatus 10 is an immunoassay apparatus that measures a test substance in a specimen by utilizing antigen-antibody reaction. The chemiluminescence measurement apparatus 10 uses a cartridge 20 to measure a test substance contained in a specimen by chemiluminescence measurement.

The chemiluminescence represents light generated by using energy caused by chemical reaction, for example, represents light emitted when molecules excited into an excited state by chemical reaction, are returned from the excited state to a ground state. The chemiluminescence can be generated, for example, by reaction between an enzyme and a substrate, by application of electrochemical stimuli to a labeling substance, by an LOCI (luminescent oxygen channeling immunoassay), or according to bioluminescence. The chemiluminescence measurement refers to measurement of chemiluminescence. A process required for chemiluminescence measurement is a process required until the chemiluminescence is measured. The process required for chemiluminescence measurement includes a process for generating the chemiluminescence. Examples of the process for generating the chemiluminescence include: a process for causing a luminescent substrate and a catalyst to react with each other; a process for applying electrochemical stimuli to a labeling substance; a process for applying light to generate singlet oxygen, and oxidizing an olefin compound by the generated singlet oxygen according to the LOCI (luminescent oxygen channeling immunoassay); and a process for generating bioluminescence by luciferin/luciferase. In Embodiment 1, the process required for chemiluminescence is, for example, the process steps of steps S12 to S18 described below. For example, controlling of a ventilator 350, by a controller 301, according to a temperature sensor 178, and controlling of a temperature of a cartridge 200 by heaters 321, 322 are also included in the process required for chemiluminescence.

The chemiluminescence measurement apparatus 10 includes a support member 31, a rotation shaft 32, a motor 40, a magnet 50, a movement mechanism 60, a light receiving unit 70, and a light-shielding portion 80. The cartridge 20 is used for measuring a test substance by chemiluminescence measurement. In FIG. 1A, the XYZ-axes are orthogonal to each other. The X-axis positive direction represents the rearward direction, the Y-axis positive direction represents the leftward direction, and the Z-axis positive direction represents the vertically downward direction.

The support member 31 supports the cartridge 20. The rotation shaft 32 extends in the vertical direction. The upper end of the rotation shaft 32 is fixed by the support member 31, and the lower end of the rotation shaft 32 is fixed to a drive shaft 41 of the motor 40. The motor 40 includes the drive shaft 41, a magnet 42, and a coil 43. The drive shaft 41 protrudes upward from the main body of the motor 40, and the magnet 42 and the coil 43 are stored in the main body of the motor 40. The magnet 42 is fixed to the lower end of the drive shaft 41, and the coil 43 is disposed so as to surround the magnet 42. When electric current passes through the coil 43, the magnet 42 and the drive shaft 41 rotate, and the rotation shaft 32 connected to the drive shaft 41 rotates.

The motor 40 rotates the support member 31 by rotating the rotation shaft 32 so as to rotate the cartridge 20 such that the process required for chemiluminescence measurement proceeds in the cartridge 20. The cartridge 20 is rotated about the rotation shaft 32. Hereinafter, the radial direction and the circumferential direction of a circle around the rotation shaft 32 are simply referred to as “radial direction” and “circumferential direction”, respectively.

As shown in FIG. 1B, the cartridge 20 is a replaceable component that collectively has functions required for detection of a test substance. The cartridge 20 is formed by a substrate 20 a that is plate-shaped and disk-shaped. The cartridge 20 may not be plate-shaped and may include a protrusion or the like, and may not be disk-shaped and may have another shape such as a rectangular shape.

The substrate 20 a has a hole 21, a first chamber 22 a, a second chamber 22 b, and a channel 23 formed therein. The hole 21 penetrates through the substrate 20 a at the center of the substrate 20 a. The cartridge 20 is placed at the chemiluminescence measurement apparatus 10 such that the center of the hole 21 is aligned with the rotation shaft 32.

The first chamber 22 a and the second chamber 22 b are each a storage portion that is provided in the cartridge 20 for storing a sample prepared from a test substance and a predetermined reagent. The first chamber 22 a and the second chamber 22 b may not constantly store liquid, and each of the first chamber 22 a and the second chamber 22 b is merely required to be spatially spread for storing liquid. The channel 23 is a passage provided in the cartridge 20 for transferring the magnetic particles.

The first chamber 22 a and the second chamber 22 b are disposed so as to be aligned in the circumferential direction. The first chamber 22 a stores a complex in which a test substance and the magnetic particles bind to each other. The first chamber 22 a is a chamber in which the complex and a first reagent are mixed. The second chamber 22 b is a chamber in which the complex and a second reagent are mixed. The channel 23 connects to the first chamber 22 a and the second chamber 22 b from the rotation shaft 32 side. The channel 23 is provided for transferring the complex from the first chamber 22 a to the second chamber 22 b.

The channel 23 includes a first region 23 a, a second region 23 b, and a third region 23 c. The first region 23 a extends in the radial direction, and connects to the first chamber 22 a. The second region 23 b extends in the radial direction, and connects to the second chamber 22 b. The third region 23 c extends in the circumferential direction. Both ends of the third region 23 c connect to the first region 23 a and the second region 23 b. A gas phase portion that is filled with gas is in at least a part of the channel 23.

Both the ends of the third region 23 c may not necessarily connect to the first region 23 a and the second region 23 b. For example, the third region 23 c that connects to the first region 23 a and the third region 23 c that connects to the second region 23 b may be separately provided, and a channel therebetween may be curved so as to be U-shaped. A liquid phase may be in the channel that is curved so as to be U-shaped. The first region 23 a and the second region 23 b may extend, in a horizontal plane, in directions that deviate from the radial direction and are different from the circumferential direction. The first region 23 a and the second region 23 b may not be provided, and the first chamber 22 a and the second chamber 22 b may connect directly to the third region 23 c.

Returning to FIG. 1A, the magnet 50 acts to collect a complex that spreads in the first chamber 22 a, to transfer the complex from the first chamber 22 a through the channel 23 into the second chamber 22 b. The magnet 50 may be implemented as a permanent magnet, or may be implemented as an electromagnet. The movement mechanism 60 moves the magnet 50 in the radial direction and the vertical direction in order to transfer the complex from the first chamber 22 a through the channel 23 into the second chamber 22 b. That is, the movement mechanism 60 moves the magnet 50 so as to be close to the rotation shaft 32 and distant from the rotation shaft 32, and moves the magnet 50 so as to be close to the cartridge 20 and distant from the cartridge 20.

In a case where the first region 23 a and the second region 23 b extend in the directions that deviate from the radial direction, the movement mechanism 60 moves the magnet 50 in the directions that deviate from the radial direction. The movement mechanism 60 may move the magnet 50 in the direction that deviates from the vertical direction when the magnet 50 is moved so as to be close to the cartridge 20 and distant from the cartridge 20.

The movement mechanism 60 is merely required to move the magnet 50 relative to the cartridge 20. For example, the movement mechanism 60 may move the cartridge 20 by moving the support member 31 that supports the cartridge 20, to move the magnet 50 relative to the cartridge 20. In a case where the support member 31 is moved, a component for moving the support member 31 needs to be separately provided. Therefore, the size of the chemiluminescence measurement apparatus 10 may be increased. Accordingly, the magnet 50 is preferably moved relative to the cartridge 20 without moving the support member 31.

The movement mechanism 60 moves the magnet 50 so as to be close to the cartridge 20 at a position opposing the first chamber 22 a, and allows the complex to be collected by magnetic force of the magnet 50. Thereafter, the movement mechanism 60 maintains the magnet 50 such that the magnet 50 is close to the cartridge 20, until the complex is moved to the second chamber 22 b.

The movement mechanism 60 moves, by moving the magnet 50 in the radial direction from the position opposing the first chamber 22 a, the complex collected by the magnet 50 in the first chamber 22 a, from the first chamber 22 a, to the channel 23. Subsequently, the motor 40 operates to rotate the cartridge 20, whereby the complex collected by the magnet 50 is moved in the channel 23. Subsequently, the movement mechanism 60 moves, by moving the magnet 50 in the radial direction from the position opposing the channel 23, the complex collected by the magnet 50, from the channel 23, to the second chamber 22 b.

By a test substance being bound to the magnetic particles, the test substance is transferred in the cartridge 20 by the magnet 50. However, the magnetic particles may not necessarily be used. For example, by pressure being applied into the cartridge 20, a test substance may be transferred. Alternatively, a test substance may be transferred by centrifugal force.

The light receiving unit 70 has a light receiver 70 a on its upper surface. A light receiving surface 70 b of the light receiver 70 a opposes the lower surface of the cartridge 20. The light receiver 70 a receives, at the light receiving surface 70 b, light generated by chemiluminescence in the cartridge 20 which is supported by the support member 31 having been rotated by the motor 40. The light receiver 70 a is a light receiver capable of performing photon counting. The light receiver 70 a outputs a pulse waveform according to photons. The light receiving unit 70 has a circuit thereinside, and counts photons at regular intervals on the basis of an output signal from the light receiver 70 a, and outputs the counted value.

The cartridge 20 supported by the support member 31, the magnet 50, the movement mechanism 60, and the light receiving surface 70 b of the light receiver 70 a are disposed in a dark space 81 surrounded by the light-shielding portion 80. In Embodiment 1, the dark space 81 is a space surrounded by the light-shielding portion 80. In Embodiment 1, the dark space 81 is not particularly limited, and may be a space having such darkness as to stably detect chemiluminescence. For example, the dark space 81 is a space that is surrounded by the light-shielding portion 80 such that the number of incident photons detected in the dark space 81 is less than or equal to 10000/(mm²·sec.) in a state where chemiluminescence is not generated in the cartridge 20. The state where chemiluminescence is not generated in the cartridge 20 is, for example, a state where the cartridge 20 is not set, or a state where power supply of the apparatus is off. From the viewpoint of a test substance being detected with enhanced sensitivity, the dark space 81 is a space surrounded by the light-shielding portion 80 such that the number of incident photons detected in the dark space 81 is preferably less than or equal to 1000/(mm² sec.), and more preferably less than or equal to 100/(mm² sec.) in a state where chemiluminescence is not generated in the cartridge 20.

In FIG. 1A, not only the light receiving surface 70 b but also the light receiving unit 70 is disposed inside the dark space 81. Meanwhile, the motor 40 is disposed outside the dark space 81. The coil 43 of the motor 40 generates heat by electric current passing therethrough. A position at which the motor 40 is disposed is represented by a position of the coil 43. Therefore, in a case where “the motor 40 is disposed outside the dark space 81”, at least the coil 43 that is a heat source is positioned outside the dark space 81, and the components, such as the drive shaft 41, other than the coil 43 may be disposed inside the dark space 81 as shown in FIG. 1A.

In the chemiluminescence measurement apparatus 10 shown in FIG. 1A, the light-shielding portion 80 is disposed inside the chemiluminescence measurement apparatus 10, and is formed from a plurality of members having light-shielding properties. The light-shielding portion 80 is formed from a resin. When the light-shielding portion 80 is formed from a resin, the light-shielding portion 80 can be easily formed. The inner side surface of the light-shielding portion 80 is black-colored. When the inner side surface of the light-shielding portion 80 is black-colored, light-shielding properties by the light-shielding portion 80 are enhanced.

The light-shielding portion 80 may be formed from a metal. However, the light-shielding portion 80 is preferably formed from a rein from the viewpoint of the light-shielding portion 80 being easily formed. A part of the inner side surface of the light-shielding portion 80 may not be black-colored. However, the entirety of the inner side surface of the light-shielding portion 80 is preferably black-colored in order to enhance light-shielding properties.

In the chemiluminescence measurement apparatus 10 as described above, the cartridge 20 supported by the support member 31 and the light receiving surface 70 b are disposed inside the dark space 81 surrounded by the light-shielding portion 80, whereby light from the outside is prevented from being incident on the light receiving surface 70 b. Therefore, accuracy for chemiluminescence measurement by the light receiver 70 a can be enhanced. The motor 40 that is a heat source is disposed outside the dark space 81 formed as a closed space, whereby unstabilization of the temperature in the dark space 81 due to heat from the motor 40 can be inhibited. Therefore, chemical reaction can be stably caused in the cartridge 20.

In a case where a light source is disposed in the apparatus, and the light receiver 70 a detects light, among light emitted from the light source, which has transmitted through a sample, the intensity of light received by the light receiver 70 a is high. Therefore, a significant problem may not arise even if light slightly leaks from the outside onto the light receiver 70 a. However, in a case where the light receiver 70 a receives light generated by chemiluminescence as described above, the light receiver 70 a needs to detect low light. In this case, light-shielding accuracy by the light-shielding portion 80 needs to be enhanced such that light that leaks from the outside onto the light receiver 70 a is minimized. In the structure shown in FIG. 1A, the dark space 81 is formed by the light-shielding portion 80, and the light receiver 70 a is disposed inside the dark space 81. Thus, light from the outside can be prevented from leaking onto the light receiver 70 a.

<Specific Example of Structure>

Hereinafter, specific structures of an analyzer and a cartridge according to Embodiment 1 will be described.

An analyzer 100 corresponds to the chemiluminescence measurement apparatus 10 shown in FIG. 1A. A motor 171 corresponds to the motor 40 shown in FIG. 1A. A support member 177 corresponds to the support member 31 shown in FIG. 1A. A rotation shaft 311 corresponds to the rotation shaft 32 shown in FIG. 1A. A magnet 120 corresponds to the magnet 50 shown in FIG. 1A. A movement mechanism 130 corresponds to the movement mechanism 60 shown in FIG. 1A. A light detection unit 144 corresponds to the light receiving unit 70 shown in FIG. 1A. A light detector 144 a corresponds to the light receiver 70 a shown in FIG. 1A. A detection face 144 b corresponds to the light receiving surface 70 b shown in FIG. 1A. A protrusion 116 of a mounting member 110, an elastic member 117, and an outer circumferential portion of the mounting member 110, a housing unit 150, the upper surface of the motor 171, an elastic member 173, a lid member 175, an elastic member 174, a casing 102 a, a light-shielding member 196, a surface 183 of a mounting member 180, a protrusion 181 of the mounting member 180, and an elastic member 182 correspond to the light-shielding portion 80 shown in FIG. 1A. A dark space 340 corresponds to the dark space 81 shown in FIG. 1A. A cartridge 200 corresponds to the cartridge 20 shown in FIG. 1B.

As shown in FIG. 2A, the analyzer 100 is an immune analyzer that measures a test substance in a specimen by utilizing antigen-antibody reaction, and analyzes the test substance on the basis of the measurement result. The analyzer 100 includes a body portion 101 and a lid portion 102. Portions, of the body portion 101, other than a portion opposing the lid portion 102 are covered by a casing 101 a. Portions, of the lid portion 102, other than a portion opposing the body portion 101 are covered by the casing 102 a. The body portion 101 supports the lid portion 102 such that the lid portion 102 is openable and closable. When the cartridge 200 is attached or detached, the lid portion 102 is opened as shown in FIG. 2A. The cartridge 200 is placed at the upper portion of the body portion 101.

As shown in FIG. 2B, the cartridge 200 is formed by a substrate 200 a that is plate-shaped and disk-shaped. Components in the cartridge 200 are each formed by a not-illustrated film that covers the entire surface of the substrate 200 a being adhered over a recess formed in the substrate 200 a. The substrate 200 a and the film adhered to the substrate 200 a are formed from translucent members. The substrate 200 a has such a thickness as to facilitate adjustment of a temperature of the cartridge 200 by heaters 321, 322 described below. For example, the thickness of the substrate 200 a is several millimeters, and is specifically 1.2 mm.

The substrate 200 a includes a hole 201, chambers 211 to 216, a channel 220, six liquid storage portions 231, a liquid storage portion 232, an opening 241, a separator 242, and a channel 243. The hole 201 penetrates through the substrate 200 a at the center of the substrate 200 a. The cartridge 200 is placed at the analyzer 100 such that the center of the hole 201 is aligned with the rotation shaft 311 described below. Hereinafter, the radial direction and the circumferential direction of a circle around the rotation shaft 311 are simply referred to as “radial direction” and “circumferential direction”, respectively. The chambers 211 to 216 are aligned in the circumferential direction near the outer circumference of the substrate 200 a.

The channel 220 includes an arc-like region 221 that extends in the circumferential direction, and six regions 222 that extend in the radial direction. The region 221 connects to the six regions 222. The six regions 222 connect to the chambers 211 to 216, respectively. The six liquid storage portions 231 connect to the channel 220 through flow paths and are disposed on extensions of the regions 222 that connect to the chambers 211 to 216, respectively. The liquid storage portion 232 connects through a flow path to a flow path that connects between the region 222 that connects to the chamber 216, and the liquid storage portion 231 on the extension of the region 222 that connects to the chamber 216.

The liquid storage portion 231 stores a reagent and has a seal 231 a on the upper surface on the inner side in the radial direction. The seal 231 a can be opened when pressed from thereabove by a pressing portion 195 described below. Before the seal 231 a is opened, the reagent in the liquid storage portion 231 does not flow into the channel 220, and when the seal 231 a is opened, the inside of the liquid storage portion 231 is in communication with the channel 220, and the reagent in the liquid storage portion 231 flows into the channel 220. Specifically, when the seal 231 a is opened, the inside of the liquid storage portion 231 connects to the outside of the cartridge 200 at the position of the seal 231 a.

Similarly, the liquid storage portion 232 stores a reagent and has a seal 232 a on the upper surface on the inner side in the radial direction. The seal 232 a can be opened when pressed from thereabove by the pressing portion 195. Before the seal 232 a is opened, the reagent in the liquid storage portion 232 does not flow into the channel 220, and when the seal 232 a is opened, the inside of the liquid storage portion 232 is in communication with the channel 220, and the reagent in the liquid storage portion 232 flows into the channel 220. Specifically, when the seal 232 a is opened, the inside of the liquid storage portion 232 connects to the outside of the cartridge 200 at the position of the seal 232 a.

The seals 231 a, 232 a may be integrated with the substrate 200 a, or may be each formed by, for example, a film adhered over an opening formed in the substrate 200 a.

A blood specimen of whole blood collected from a subject is injected into the separator 242 through the opening 241. The blood specimen injected into the separator 242 is separated into blood cells and plasma in the separator 242. The plasma separated in the separator 242 is moved into the channel 243. A hole 243 a is formed on the upper surface on the inner side, in the radial direction, of the channel 243. The plasma positioned in a region 243 b of the channel 243 is moved into the chamber 211 by a centrifugal force when the cartridge 200 is rotated. Thus, a predetermined amount of plasma is transferred into the chamber 211.

The components of the substrate 200 a are provided in only one-third of the region of the substrate 200 a as shown in FIG. 2B. However, the structure is not limited thereto, and a group of the components may be provided in the remaining two-thirds of the region of the substrate 200 a, and three groups of the components may be provided in the substrate 200 a.

Subsequently, an internal structure of the analyzer 100 will be described with reference to FIG. 3 to FIG. 12B.

The mounting member 110 has holes 111 to 114 formed therein. The holes 111 to 114 penetrate through the mounting member 110. In the hole 111, the rotation shaft 311 described below is positioned. The hole 112 is elongated in the radial direction. The movement mechanism 130 is mounted on the lower surface of the mounting member 110 through a member 131. In the horizontal plane, a hole 131 a of the member 131 is aligned in position with the hole 112 of the mounting member 110. The detector 140 is mounted on the lower surface of the mounting member 110 through a member 141. In the horizontal plane, a reflector 142 of the detector 140 is aligned in position with the hole 113 of the mounting member 110. In the hole 114, a temperature sensor 178 described below is mounted. Protrusions 115, 116 which are each shaped into a closed-loop are formed on the upper surface of the mounting member 110. The protrusions 115, 116 protrude upward along the circumferential direction.

A housing unit 150 has an upper surface 151, housings 152, 153, and an outer surface 154. At the center of the upper surface 151, a hole 155 is formed so as to penetrate through the upper surface 151 to the outer surface 154 in the up-down direction. The hole 155 allows the rotation shaft 311 described below to pass therethrough. The housings 152, 153 are formed as recesses that are recessed downward from the upper surface 151. The mounting member 110 having the movement mechanism 130 and the detector 140 mounted thereto is mounted in the housing unit 150. When the mounting member 110 is mounted in the housing unit 150, the lower surface of the outer perimeter of the mounting member 110 and the upper surface of the outer perimeter of the housing unit 150 are jointed to each other. When the mounting member 110 is mounted in the housing unit 150, the movement mechanism 130 is housed in the housing 152 and the detector 140 is housed in the housing 153.

The mounting member 110 and the housing unit 150 are each formed from a light-shielding resin, and the mounting member 110 and the housing unit 150 are black-colored in order to enhance light-shielding properties. A not-illustrated predetermined elastic member is provided between the lower surface of the outer perimeter of the mounting member 110 and the upper surface of the outer perimeter of the housing unit 150. The predetermined elastic member is formed from, for example, light-shielding chloroprene rubber and polyurethane resin, and the predetermined elastic member is black-colored in order to enhance light-shielding properties.

As shown in FIG. 4A, the movement mechanism 130 includes the member 131, two support shafts 132, a gear portion 133, a supporter 134, a motor 135, a transmission gear 135 a, a motor 136, transmission gears 136 a to 136 c, a screw 137, and a supporter 138. The two support shafts 132 are disposed on the lower surface of the member 131. The gear portion 133 is disposed on the side surface of the member 131 and is flat-plate-shaped. The supporter 134 is supported so as to be movable relative to the two support shafts 132. The two support shafts 132 extend in the radial direction. A hole 134 a is formed in the upper surface of the supporter 134. The hole 134 a is aligned in position with the hole 131 a of the member 131 in the horizontal plane.

The supporter 134 supports the motors 135, 136, the transmission gear 136 b, and the screw 137. The motors 135, 136 are implemented as stepping motors. When the drive shaft of the motor 135 is rotated, the transmission gear 135 a mounted to the drive shaft is rotated, and driving force is transmitted to the gear portion 133. Thus, the supporter 134 is moved in the radial direction while being supported by the two support shafts 132.

When the drive shaft of the motor 136 is rotated, the transmission gear 136 a mounted to the drive shaft is rotated. The transmission gears 136 a and 136 b mesh with each other, and the transmission gears 136 b and 136 c mesh with each other. The transmission gear 136 b is rotatably mounted to the supporter 134, and the transmission gear 136 c is mounted to the screw 137. The screw 137 is rotatably supported by the supporter 134. The supporter 138 is supported by the screw 137 so as to be moved in the up-down direction according to rotation of the screw 137. The magnet 120 is mounted to the supporter 138. Therefore, when the drive shaft of the motor 136 is rotated, driving force is transmitted to the transmission gears 136 a, 136 b, 136 c and the screw 137. Thus, the supporter 138 is moved in the up-down direction.

When the movement mechanism 130 is thus structured, the magnet 120 can be moved in the radial direction according to the motor 135 being driven, and the magnet 120 can be moved in the up-down direction according to the motor 136 being driven. According to the magnet 120 being moved inward in the radial direction, the upper end of the magnet 120 is moved inward in the radial direction of the cartridge 200. According to the magnet 120 being moved outward in the radial direction, the upper end of the magnet 120 is moved outward in the radial direction of the cartridge 200. According to the magnet 120 being moved upward, the upper end of the magnet 120 protrudes upward through the holes 131 a, 134 a, and is moved close to the cartridge 200. According to the magnet 120 being moved downward, the upper end of the magnet 120 is moved so as to be distant from the cartridge 200.

As the structure for changing a position of the magnet 120 relative to the cartridge 200, a structure other than the above-described structure may be used. For example, in order to move the magnet 120 in the up-down direction, the magnet 120 may be extended and contracted, or the magnet 120 may be rotated about a direction parallel to the horizontal direction.

As shown in FIG. 4B, the magnet 120 includes a permanent magnet 121 and a magnetic body 122. The magnetic body 122 may be either a paramagnetic body or a ferromagnetic body, or may be a combination thereof. The permanent magnet 121 has a cylindrical shape, and the magnetic body 122 has a conic shape. The magnetic body 122 is joined to the upper surface of the permanent magnet 121. At the upper end of the magnetic body 122, a tip portion 122 a is formed. The tip portion 122 a has a columnar shape having a constant cross-sectional area when cut at the horizontal plane. Specifically, the tip portion 122 a has a cylindrical shape. The magnet 120 may have any shape that is tapered such that the closer the cartridge 200 side portion of the magnet 120 is to the cartridge 200, the less the cross-sectional area of the magnet 120 is.

By the magnet 120, a magnetic force is exerted such that the larger the permanent magnet 121 is, in other words, the larger the cross-sectional area of the horizontal surface of the permanent magnet 121 is, the higher the magnetic force exerted onto the magnetic particles in the cartridge 200 is. The less an angle θ of the tapered shape of the magnet 120 is, the more greatly a magnetic force from a central axis 120 a of the magnet 120 varies. The less the angle θ is, the higher a force for moving the magnetic particles in the cartridge 200 is. However, in a case where the cross-sectional area of the horizontal surface of the permanent magnet 121 is constant, the less the angle θ is, the longer a distance from the tip portion 122 a to the upper surface of the permanent magnet 121 is, so that a magnetic force exerted onto the cartridge 200 by the magnet 120 is reduced. Therefore, in order to increase both a magnetic force exerted onto the magnetic particles and a force for moving the magnetic particles in a well-balanced manner, the angle θ is set as, for example, 60° in Embodiment 1.

In a case where a magnetic force exerted onto the magnetic particles and a force for moving the magnetic particles are high, when the magnetic particles are moved in the cartridge 200 by the magnet 120, the magnetic particles can be prevented from being left behind. Therefore, in a case where the magnet 120 is structured as shown in FIG. 4B, since both a magnetic force exerted onto the magnetic particles and a force for moving the magnetic particles can be increased in a well-balanced manner, the magnetic particles can be prevented from being left behind, and unintended reduction of an amount of light detected by the detector 140 can be inhibited. Therefore, false-negative due to the unintended reduction of an amount of light can be inhibited, thereby allowing highly accurate detection.

The width of the edge of the magnet 120 on the cartridge 200 side, that is, the width of the tip portion 122 a is less than at least the minimal width of each region in the channel 220. Thus, a complex collected by the magnet 120 can be smoothly moved in the channel 220 so as not to be caught by the channel 220.

The magnet 120 may be formed only by a permanent magnet. That is, the magnet 120 may be formed as a permanent magnet having a shape obtained by combining the permanent magnet 121 and the magnetic body 122 as described above with each other. However, the magnet 120 that includes the permanent magnet 121 and the magnetic body 122 can be more simply formed with higher accuracy as compared to the magnet 120 having the combined shape.

As shown in FIG. 5A, the detector 140 includes the member 141, the reflector 142, a supporter 143, a light detection unit 144, and a light adjuster 160. The member 141 has a hole 141 a that penetrates through the member 141 in the up-down direction. The reflector 142 is disposed so as to be fitted into the hole 141 a formed in the member 141. The supporter 143 is disposed on the lower surface of the member 141. The light detection unit 144 and the light adjuster 160 are mounted in the supporter 143.

As shown in FIGS. 5B, 5C, the reflector 142 has a transparent plate 142 a in the upper portion thereof. The transparent plate 142 a is a member for protecting a light detector 144 a described below. The optical effect by the transparent plate 142 a can be substantially ignored, and illustration of the transparent plate 142 a is omitted for convenience in the following figures. The reflector 142 has, at the center thereof, a hole 142 b that penetrates therethrough in the up-down direction. The diameter of the hole 142 b in the horizontal plane is reduced downward in the vertical direction. Even if a complex is positioned at any of the center and the end portions in the chamber 216, the reflector 142 allows light generated from the inside of the chamber 216 to be guided to the same degree toward the light detector 144 a.

FIG. 6A shows a state where the member 141 and the reflector 142 are removed from the detector 140 shown in FIG. 5A.

As shown in FIG. 6A, the light adjuster 160 has a motor 161 and a plate-shaped member 162. The motor 161 is implemented as a stepping motor. The plate-shaped member 162 is mounted to a drive shaft 161 a of the motor 161, and includes holes 162 a, 162 b. The holes 162 a, 162 b penetrate through the plate-shaped member 162 in the up-down direction. In the hole 162 b, a filter member 162 c is mounted. The filter member 162 c is an ND filter. When the motor 161 is driven, the plate-shaped member 162 is rotated about the drive shaft 161 a. Thus, the hole 162 a, the filter member 162 c, or a region 162 d, other than the holes 162 a, 162 b, of the plate-shaped member 162 is positioned vertically above the light detector 144 a of the light detection unit 144.

The light detection unit 144 has the light detector 144 a on the upper surface. The light detector 144 a has the detection face 144 b that opposes the plate-shaped member 162. The light detector 144 a optically detects a test substance stored in the chamber 216. The light detector 144 a may be structured so as to perform chemiluminescence measurement, and is implemented as, for example, a photomultiplier, a phototube, or the like. The light detector 144 a outputs a pulse waveform based on photons. The light detection unit 144 has a circuit thereinside, and counts photons at regular intervals on the basis of the output signal from the light detector 144 a and outputs the counted value.

As shown in FIG. 6B, light generated from the chamber 216 of the cartridge 200 spreads upward and downward of the cartridge 200. The light that has spread downward of the cartridge 200 passes through the hole 142 b of the reflector 142, passes through the filter member 162 c or the hole 162 a of the light adjuster 160, and is received by the light detector 144 a. The light that has spread upward of the cartridge 200 is reflected by a plate member 191 of the lid portion 102 as described below, and is returned to the chamber 216, and is similarly received by the light detector 144 a. A mirror may be mounted to the plate member 191 of the lid portion 102, to reflect the light that has spread upward of the cartridge 200.

As shown in FIG. 7, the outer surface 154 of the housing unit 150 is positioned on the lower side of the housing unit 150, and positioned at the center of the housing unit 150 in the horizontal plane. The outer surface 154 is parallel to the horizontal plane. At the center of the outer surface 154, an outlet of the hole 155 that penetrates through the upper surface 151 to the outer surface 154 in the up-down direction, is formed. The outer surface 154 has a recess 154 a around the outlet of the hole 155. The recess 154 a has a ring-shaped outer shape as viewed in the vertically upward direction. In the hole 155, a hole 156 is formed so as to be in communication with the outside, from the side of the hole 155.

The motor 171 is implemented as a stepping motor. A stepping motor is advantageous in that, since its rotation speed is proportional to a frequency of an input pulse, a wide range of rotation speeds can be realized, and positioning can be accurately performed. Meanwhile, a stepping motor has a disadvantage that efficiency of energy is poor. In Embodiment 1, since the motor 171 is disposed outside the dark space formed as a closed space, the disadvantage of a stepping motor that efficiency of energy is poor and heat is easily generated, can be reduced. In Embodiment 1, as described below, the motor 171 operates so as to transfer, into the chambers 211 to 216, reagents stored in the six liquid storage portions 231 and a reagent stored in the liquid storage portion 232 by centrifugal force generated when the cartridge 200 is rotated at a predetermined speed. In Embodiment 1, liquid stored in the chamber is agitated by switching the rotation speed at predetermined time intervals. In step S102 described below, a speed at which a complex is moved relative to the cartridge 200 is preferably lower than or equal to 10 mm/second so as not to leave the complex in the chamber 211. In such a situation, in particular, positioning is required to be accurately performed and a wide range of rotation speeds are required to be realized. Therefore, the motor 171 is particularly preferably disposed outside the dark space formed as a closed space because the disadvantage of a stepping motor that efficiency of energy is poor and heat is easily generated can be reduced.

An encoder 172 is mounted on the lower surface of the motor 171, and detects rotation of a rotation shaft of the motor 171. An elastic member 173 is formed from, for example, a light-shielding polyurethane resin, and the elastic member 173 is black-colored in order to enhance light-shielding properties. The outer shape of the elastic member 173 is ring-shaped such that the elastic member 173 is fitted into the recess 154 a of the outer surface 154. The motor 171 is mounted to the outer surface 154 so as to close the hole 155. Specifically, the elastic member 173 is disposed in the recess 154 a between the outer surface 154 and the upper surface of the motor 171 that opposes the outer surface 154 such that the elastic member 173 surrounds the hole 155. The motor 171 is mounted on the outer surface 154 so as to press the upper surface of the motor 171 against the elastic member 173. Thus, the lower portion of the hole 155 is closed by the elastic member 173 and the upper surface of the motor 171.

When the motor 171 has been mounted to the outer surface 154, connection and the like of the mechanisms inside the hole 155 are subsequently performed through the hole 156. When the connection and the like of the mechanisms are ended, the elastic member 174 is disposed around the outlet of the hole 156, and the hole 156 is closed by a lid member 175. The elastic member 174 and the lid member 175 are formed so as to have light-shielding properties.

As shown in FIG. 8, a plate member 176 and the support member 177 are mounted in a portion, within the protrusion 115, of the mounting member 110. The plate member 176 is formed from a metal having a high thermal conductivity. The heater 321 described below is mounted on the lower surface of the plate member 176. The plate member 176 and the heater 321 have holes at positions corresponding to the holes 111 to 114 of the mounting member 110 shown in FIG. 3. The movement mechanism 130, the detector 140, and the temperature sensor 178 directly oppose the lower surface of the cartridge 200 through these holes as shown in FIG. 8. The temperature sensor 178 is mounted on the lower surface side of the mounting member 110. The temperature sensor 178 detects a temperature of the cartridge 200 by infrared rays.

The support member 177 is mounted at the center of the mounting member 110 through a mounting member 310 described below. The support member 177 is implemented as, for example, a turntable. An elastic member 117 is disposed between the protrusion 115 and the protrusion 116. The elastic member 117 is formed from, for example, a light-shielding polyurethane resin. The elastic member 117 is black-colored in order to enhance light-shielding properties. The elastic member 117 is formed into a closed-loop shape. The upper surface of the elastic member 117 is an elastically deformable joint surface. The mounting member 110 and the housing unit 150 that are thus assembled are mounted in the casing 101 a to complete the body portion 101.

FIG. 8 shows the lid portion 102 as viewed from therebelow. The lid portion 102 includes the mounting member 180, the plate member 191, a clamper 192, an imaging portion 193, an illumination portion 194, and the pressing portion 195.

The mounting member 180 is formed from a light-shielding resin, and the mounting member 180 is black-colored in order to enhance light-shielding properties. The plate member 191 and the clamper 192 are disposed in a portion, within the protrusion 181, of the mounting member 180. The plate member 191 is formed from a metal having a high thermal conductivity, similarly to the plate member 176. The heater 322 described below is mounted to the upper surface of the plate member 191. The lower surface of the mounting member 180, the plate member 191, and the heater 322 have holes at positions corresponding to the imaging portion 193, the illumination portion 194, and the pressing portion 195. The imaging portion 193, the illumination portion 194, and the pressing portion 195 directly oppose the upper surface of the cartridge 200 through the holes. The imaging portion 193, the illumination portion 194, and the pressing portion 195 are disposed on the upper surface of the mounting member 180.

The imaging portion 193 takes an image representing a state in the cartridge 200. The imaging portion 193 is implemented as a small camera. The small camera includes, for example, a CCD image sensor, a CMOS image sensor, or the like. The illumination portion 194 illuminates the cartridge 200 when the imaging portion 193 performs image-taking. The illumination portion 194 is implemented as, for example, a light emitting diode. The pressing portion 195 opens the seals 231 a, 232 a by pressing the seals 231 a, 232 a. The pressing portion 195 will be described below with reference to FIGS. 10A to 10C.

The clamper 192 is disposed at the center of the mounting member 180. On the lower surface of the mounting member 180, the protrusion 181 that is shaped into a closed-loop is formed. The protrusion 181 protrudes downward along the circumferential direction. On the lower surface of the mounting member 180, a recess is formed outward of the protrusion 181, and the elastic member 182 is disposed in the recess. The elastic member 182 is formed from, for example, a light-shielding polyurethane resin, and the elastic member 182 is black-colored in order to enhance light-shielding properties. The elastic member 182 is shaped into a closed loop. The lower surface of the elastic member 182 is an elastically deformable joint surface.

When assembled, the lid portion 102 is mounted to the body portion 101 so as to be openable and closable relative to the mounting member 110 of the body portion 101. A ventilator 350 described below is mounted in the casing 101 a of the body portion 101. The ventilator 350 will be described below with reference to FIGS. 12A, 12B.

FIG. 9 is a schematic diagram illustrating a cross-section of the analyzer 100 taken when cut at a plane that is parallel to the YZ-plane and that passes through the rotation shaft 311. FIG. 9 shows a state where the cartridge 200 is disposed at the analyzer 100 and the lid portion 102 is closed. On the lower surface of the mounting member 110, the movement mechanism 130 that holds the magnet 120, and the detector 140 are mounted as described above. On the upper surface of the mounting member 180, the imaging portion 193, the illumination portion 194, and the pressing portion 195 are mounted as described above. In FIG. 9, positions corresponding to positions at which these components are disposed are indicated by dashed lines.

As shown in FIG. 9, a drive shaft 171 a of the motor 171 extends into the hole 155 by the motor 171 being disposed at the outer surface 154. The mounting member 310 is mounted at the upper portion of the hole 155. The mounting member 310 supports the rotation shaft 311 that extends in the up-down direction such that the rotation shaft 311 is rotatable. The rotation shaft 311 is fixed, in the hole 155, to the drive shaft 171 a of the motor 171 by the fixing member 312.

The support member 177 for supporting the lower surface of the cartridge 200 is fixed through a predetermined member to the upper portion of the rotation shaft 311. When the motor 171 is driven and the drive shaft 171 a is rotated, a rotation driving force is transmitted to the support member 177 through the rotation shaft 311. Thus, the cartridge 200 placed on the support member 177 is rotated about the rotation shaft 311 and the drive shaft 171 a. When the cartridge 200 is placed on the support member 177 and the lid portion 102 is closed, the clamper 192 presses the inner circumferential portion of the upper surface of the cartridge 200 such that the cartridge 200 is rotatable.

The heater 321 is mounted on the lower surface of the plate member 176, and the heater 322 is mounted on the upper surface of the plate member 191. In the heaters 321, 322, a heat generating surface is a plane, and the heat generating surface is disposed so as to be parallel to the cartridge 200. Thus, the cartridge 200 can be efficiently heated. Temperature sensors 331, 332 shown in FIG. 13 are disposed at the plate members 176, 191, respectively. The temperature sensors 331, 332 detect temperatures of the plate members 176, 191, respectively.

The controller 301 described below drives the heaters 321, 322 such that a temperature, of the plate member 176, detected by the temperature sensor 331 in analysis and a temperature, of the plate member 191, detected by the temperature sensor 332 in analysis are predetermined temperatures. The controller 301 drives the heaters 321, 322, on the basis of temperatures detected by the temperature sensors 331, 332, in a control method such as P control, PD control, or PID control. Thus, the temperature of the cartridge 200 is maintained at a predetermined temperature. In Embodiment 1, the predetermined temperature is 42° C. such that reaction in the cartridge 200 appropriately proceeds. Thus, it is particularly important in immunoassay to maintain the temperature of the cartridge 200 so as to be constant. The controller 301 may drive the heaters 321, 322 on the basis of the temperature detected by the temperature sensor 178.

The movement mechanism 130 and the detector 140 act so as to exert a magnetic force onto the cartridge 200 and receive light generated from the cartridge 200 side as indicated by dashed arrows in FIG. 9. On the lower side of the cartridge 200, the mounting member 110 allows light to be easily transmitted in the up-down direction. However, below the mounting member 110, the housing unit 150 is positioned, thereby preventing light from passing between a space below the cartridge 200 and the outside.

Above the mounting member 180 of the lid portion 102, the light-shielding member 196 is disposed between the inner surface of the casing 102 a and the mounting member 180. The light-shielding member 196 is formed from a light-shielding resin, and the light-shielding member 196 is black-colored in order to enhance light-shielding properties. A not-illustrated predetermined elastic member is disposed between the lower surface of the outer perimeter of the light-shielding member 196, and the upper surface of the outer perimeter of the mounting member 180. The predetermined elastic member is formed from, for example, light-shielding chloroprene rubber and polyurethane resin, and the predetermined elastic member is black-colored in order to enhance light-shielding properties.

The mounting member 180 has holes at positions where the imaging portion 193, the illumination portion 194, and the pressing portion 195 are disposed. Therefore, at the positions where these components are disposed, light leaks therein in the up-down direction. Accordingly, the mounting member 180 allows light to be transmitted in the up-down direction on the upper side of the cartridge 200. However, the light-shielding member 196 is positioned above the mounting member 180. Thus, light is prevented from passing between a space above the cartridge 200 and the outside.

When the lid portion 102 is closed, the protrusion 116 of the mounting member 110 is pressed against and comes into close contact with the lower surface of the elastic member 182 of the mounting member 180. The protrusion 181 of the mounting member 180 is pressed against and comes into close contact with the upper surface of the elastic member 117 of the mounting member 110. A surface 183 is formed on the lower surface, near the outer perimeter, of the mounting member 180, and a lateral side portion of the inner portion inside the lid portion 102 is covered by the casing 102 a. Thus, light is prevented from passing between a space lateral to the cartridge 200 and the outside.

Thus, a dark space 340 indicated by dashed lines in FIG. 9 is formed by a light-shielding portion. The light-shielding portion on the body portion 101 side is formed by the protrusion 116 of the mounting member 110, the elastic member 117, the outer perimeter portion of the mounting member 110, the housing unit 150, the upper surface of the motor 171, the elastic member 173, the lid member 175, and the elastic member 174. The light-shielding portion on the lid portion 102 side is formed by the casing 102 a, the light-shielding member 196, the surface 183 of the mounting member 180, the protrusion 181 of the mounting member 180, and the elastic member 182. When the lid portion 102 is closed, the light-shielding portion on the body portion 101 side and the light-shielding portion on the lid portion 102 side are joined to each other in portions lateral to the cartridge 200, and the dark space 340 is surrounded by the light-shielding portions. Thus, light is prevented from leaking into the light-shielding portion. The structure of the light-shielding portion is an exemplary structure, and the components and the like of the light-shielding portion are not limited to the above-described ones.

As shown in FIG. 3, the upper surface 151 and the housings 152, 153 of the housing unit 150 have holes through which cables pass. The holes may be holes that are opened in the dark space 340. Therefore, the holes through which the cables and the like pass for exchanging signals between the inside of the dark space 340 and the outside of the dark space 340 are all closed by the light-shielding member in order to form the dark space 340. For example, a light-shielding tape, a light-shielding fabric, a heat-shrinkable tube, a grommet, a caulking material, or the like can be used so as to shield gaps between the cables and the holes from light at the outlets of the holes. The light-shielding members are black-colored in order to enhance light-shielding properties.

When the dark space 340 is formed as described above, the support member 177 that supports the cartridge 200, the cartridge 200, and the detection face 144 b of the light detector 144 a are disposed in the dark space 340. In Embodiment 1, the magnet 120, the movement mechanism 130, and the detector 140 are disposed in the dark space 340. Thus, even if light generated in reaction in the chamber 216 is extremely low, since light does not enter the dark space 340 from the outside, light generated in the reaction can be accurately detected by the light detector 144 a. Therefore, accuracy for analyzing a test substance can be enhanced.

Since the cartridge 200 is disposed inside the dark space 340, if the magnet 120 that needs to access the cartridge 200 is outside the dark space 340, a hole needs to be formed in the light-shielding member that forms the dark space 340 so as to allow the magnet 120 to pass therethrough. In this case, the hole may become relatively large unlike a hole through which a cable merely passes. Therefore, it is difficult to maintain high light-shielding properties in the dark space 340 with a simple structure. Meanwhile, in Embodiment 1, since the magnet 120 that accesses the cartridge 200 is disposed inside the dark space 340, a hole through which the magnet 120 passes need not be formed. Thus, high light-shielding properties required for chemiluminescence measurement can be maintained in the dark space 340 with a simple structure.

If the movement mechanism 130 that moves the magnet 120 is outside the dark space 340, similarly to a case where the magnet 120 is outside the dark space 340, a hole needs to be formed in the light-shielding member that forms the dark space 340 so as to allow the magnet 120 or the movement mechanism 130 to pass therethrough. Also in this case, the hole may become relatively large unlike a hole through which a cable merely passes. Therefore, it is difficult to maintain high light-shielding properties in the dark space 340 with a simple structure. The movement mechanism 130 includes the motor 135 and the motor 136, and the motor 135 and the motor 136 are smaller than the motor 171 that rotates the cartridge 200. The inventors have found that, even if such a small motor as to move the magnet 120 is disposed inside the dark space 340, influence of the temperature on the dark space 340 is less than that by the motor 171. Thus, in Embodiment 1, the movement mechanism 130 can be disposed inside the dark space 340, and high light-shielding properties required for chemiluminescence measurement can be thus maintained in the dark space 340 with a simple structure.

The motor 171 includes a coil that generates heat by electric current passing therethrough, similarly to the structure shown in FIG. 1A. A position at which the motor 171 is disposed is represented by a position of the coil of the motor 171. Therefore, in a case where “the motor 171 is disposed outside the dark space 340”, at least the coil that is a heat source is positioned outside the dark space 340, and the components, other than the coil, of the motor 171, for example, the drive shaft 171 a may be disposed inside the dark space 340 as shown in FIG. 9.

As described above, the motor 171 is disposed outside the dark space 340. When the cartridge 200 is rotated, the motor 171 is excited and heat is generated from the coil. However, when the motor 171 which is a heat source is disposed outside the dark space 340 formed as a closed space as described above, unstabilization of the temperature in the dark space 340 due to heat from the motor 171 can be inhibited. Thus, the temperature of the cartridge 200 can be maintained at a desired temperature. Therefore, a specimen and a reagent in the cartridge 200 can be caused to stably react.

As shown in FIGS. 10A to 10C, the pressing portion 195 includes a mounting member 361, a motor 362, transmission gears 363 a, 363 b, 363 c, a screw 364, a moving member 365, a pin member 366, a roller 367, and a spring 368. In FIGS. 10A to 10C, the D1 direction represents a direction obtained by the X-axis positive direction being rotated clockwise about the Z-axis by 45°. The D2 direction represents a direction obtained by the Y-axis positive direction being rotated counterclockwise about the Z-axis by 45°. The D3 direction represents a direction obtained by the X-axis positive direction being rotated counterclockwise about the Z-axis by 45°. The D3 direction represents a radially outward direction. FIGS. 10B, 10C are each a side view illustrating a cross-section of C1-C2 shown in FIG. 10A, as viewed in the D3 direction.

As shown in FIG. 10B, the mounting member 361 is disposed on the upper surface of the mounting member 180 of the lid portion 102. As shown in FIG. 10A, the motor 362 is mounted to the mounting member 361. The motor 362 is implemented as a stepping motor. The transmission gears 363 a, 363 b, 363 c and the screw 364 are supported by the mounting member 361 so as to be rotatable about the D1-D2 direction. The transmission gears 363 a and 363 b mesh with each other, and the transmission gears 363 b and 363 c mesh with each other. A drive shaft 362 a of the motor 362 is connected to the transmission gear 363 a, and the screw 364 is connected to the transmission gear 363 c. The moving member 365 is supported by the screw 364 so as to be moved in the D1-D2 direction according to rotation of the screw 364. As shown in FIG. 10B, on the lower surface side of the moving member 365, a cam portion 365 a is formed as a plane titled relative to the horizontal plane.

As shown in FIGS. 10A, 10B, the mounting member 361 has a hole 361 a that has a cylindrical shape. As shown in FIG. 10B, the pin member 366 includes a trunk portion 366 a, a flange portion 366 b formed at the upper end of the trunk portion 366 a, and an end portion 366 c formed at the lower end of the trunk portion 366 a. The trunk portion 366 a has a cylindrical shape that extends in the Z-axis direction. The flange portion 366 b has a cylindrical shape having a diameter that is greater than the trunk portion 366 a, and that is almost equal to that of the hole 361 a. The end portion 366 c has a cylindrical shape having a diameter less than the trunk portion 366 a. The trunk portion 366 a passes through a hole formed at the bottom of the hole 361 a, and through a hole that is formed so as to correspond to the hole formed at the bottom of the hole 361 a and that penetrates through the mounting member 180, the heater 322, and the plate member 191.

The roller 367 is rotatably disposed at the upper portion of the pin member 366. The roller 367 has a cylindrical shape. The spring 368 is disposed between the lower surface of the flange portion 366 b and the bottom of the hole 361 a, and pushes the pin member 366 in the vertically upward direction.

When the pressing portion 195 is thus formed, driving force is transmitted to the transmission gears 363 a, 363 b, 363 c, and the screw 364 according to the motor 362 being driven. Thus, the moving member 365 is moved in the D1-D2 direction. When the moving member 365 is moved in the D1 direction in the state shown in FIG. 10B, the cam portion 365 a comes into contact with the roller 367 and pushes the roller 367 downward. Thus, as shown in FIG. 10C, the pin member 366 is moved downward. When the moving member 365 is moved in the D2 direction in the state shown in FIG. 10C, the cam portion 365 a is moved so as to be distant from the roller 367, and the spring 368 pushes the pin member 366 upward. Thus, the position of the pin member 366 is returned to the position shown in FIG. 10B.

When the seal 231 a is opened, the cartridge 200 is rotated by the support member 177 in a state where the pin member 366 is positioned at the upper side as shown in FIG. 10B, and the seal 231 a is positioned vertically below the end portion 366 c. The position vertically below the end portion 366 c is a position where the pressing portion 195 opens the seal 231 a. The motor 362 is driven, and the pin member 366 is moved downward as shown in FIG. 10C. Thus, the seal 231 a positioned vertically below the end portion 366 c is pressed from thereabove by the end portion 366 c, and the seal 231 a is opened. Also when the seal 232 a is opened, the seal 232 a is positioned vertically below the end portion 366 c, and the seal 232 a is opened by the pressing portion 195, similarly to the seal 231 a.

Thus, the seals 231 a, 232 a are opened by the pressing portion 195 by the seals 231 a, 232 a being pressed by the end portion 366 c. In the opening of the seals 231 a and 232 a, the seals 231 a, 232 a are pressed from thereabove by, for example, 10 N force by the end portion 366 c. When such a high force is applied to the cartridge 200, displacement, unintended deformation, or the like of the cartridge 200 may occur. Therefore, in order to inhibit the displacement and deformation, as shown in FIG. 11A, the cartridge 200 is supported from therebelow by the support member 177 at the position of the seal 231 a.

FIG. 11A illustrates the support member 177 as viewed from thereabove. In FIG. 11A, the cartridge 200 which is placed on the support member 177 is indicated by dashed lines for convenience. The movement mechanism 130 and the detector 140 portions that directly oppose the lower surface of the cartridge 200 through holes formed in the plate member 176 shown in FIG. 8, are indicated by dashed lines for convenience. The rotation shaft 311, and the end portion 366 c of the pin member 366 are indicated by dashed lines for convenience.

As shown in FIG. 11A, r1 represents a distance from the rotation shaft 311 to the end portion 366 c in the horizontal plane. In other words, r1 represents a distance from the rotation shaft 311 to a position at which the cartridge 200 is pressed by the pressing portion 195. The support member 177 is disposed at a position opposing the pressing portion 195 across the cartridge 200. Specifically, the support member 177 is a turntable that has a radius r2 that is greater than at least the distance r1, and disposed in a portion from the rotation shaft 311 side to the position opposing the pressing portion 195.

Thus, in opening of the seals 231 a, 232 a, also when the pressing portion 195 presses the seals 231 a, 232 a, and a pressing force is applied to the cartridge 200, the cartridge 200 is supported by the support member 177 that acts as a base. Therefore, in the opening of the seals 231 a, 232 a, displacement or damage may not occur in the cartridge 200, and the cartridge 200 is appropriately supported at a predetermined position. Therefore, measurement accuracy is inhibited from being reduced by the opening.

When high force is applied to the seals 231 a, 232 a by the pressing portion 195, the support member 177 that supports the cartridge 200 may be tilted relative to the horizontal plane. In this case, in a case where the rotation shaft 311 that supports the support member 177 is tilted, the drive shaft 171 a, of the motor 171, connected to the rotation shaft 311 is tilted, and the motor 171 may be out of order. However, in Embodiment 1, the rotation shaft 311 that supports the support member 177 is supported via the mounting member 310 by the mounting member 110. Therefore, even if high force is applied to the seals 231 a, 232 a when the seals are opened, the support member 177 is inhibited from being titled, and the motor 171 can be prevented from being out of order.

As shown in FIG. 11A, the radius r2 of the support member 177 is set such that the support member 177 does not overlap the movement mechanism 130 and the detector 140 portions that directly oppose the lower surface of the cartridge 200 as viewed from thereabove. Thus, the magnet 120 can access the cartridge 200 in a state where the cartridge 200 is placed on the support member 177. Therefore, the magnetic particles collected by the magnet 120 in one chamber can be smoothly transferred to another chamber. Light from the cartridge 200 is not blocked by the support member 177, so that detection by the detector 140 can be appropriately performed.

When the radius r2 of the support member 177 is set as a great value in such a range that the support member 177 does not overlap the movement mechanism 130 and the detector 140 portions that oppose the lower surface of the cartridge 200, the cartridge 200 can be more stably supported. However, if the radius r2 of the support member 177 is increased, a load on the motor 171 that rotates the support member 177 is increased. In this case, if the rotation time of the motor 171 is increased, or a rotation speed is frequently changed, the motor 171 may be out of order or heat generation of the motor 171 may be increased. Therefore, the radius r2 of the support member 177 is preferably minimized in such a range as to cover positions at which pressing force from the pressing portion 195 is received by the support member 177.

Even if the radius r2 of the support member 177 is thus set so as to be as small a value as possible, an area and a weight of the support member 177 are increased as compared to a case where the support member simply supports the cartridge 200. In this case, the motor 171 that drives the support member 177 is increased in size, and the heat generation of the motor 171 is increased. However, as described above, the motor 171 is disposed outside the dark space 340. Therefore, even if heat generation of the motor 171 is increased, unstabilization of a temperature in the dark space 340 can be inhibited, and the measurement can appropriately proceed.

As shown in FIG. 11B, the radius for the outermost circumferential portion of the support member 177 may be set to be almost equal to the radius of the cartridge 200. In this case, for example, the support member 177 has three holes 177 a that penetrate through the support member 177 in the Z-axis direction. An inner circumferential portion 177 b having the radius r2 is formed inward of the three holes 177 a, similarly to the case shown in FIG. 11A. A connecting portion 177 c is disposed between the two holes 177 a adjacent to each other so as to extend in the radial direction. An outer circumferential portion 177 d positioned at the outermost circumference of the support member 177 is supported by the three connecting portions 177 c.

The size of the hole 177 a is set such that the movement mechanism 130 and the detector 140 portions that are open upward directly oppose the lower surface of the cartridge 200 through each hole 177 a. The size of the hole 177 a is set such that the chambers 211 to 216 and the channel 220 do not overlap the support member 177 when the cartridge 200 is placed on the support member 177.

When the support member 177 is formed as shown in FIG. 11B, the lower surface, of the cartridge 200, positioned below the seals 231 a, 232 a can be supported by the inner circumferential portion 177 b, as in the case shown in FIG. 11A. In the case shown in FIG. 11B, a portion, of the cartridge 200, near the outer circumference is supported by the outer circumferential portion 177 d, whereby the cartridge 200 can be more stably supported as compared to the case shown in FIG. 11A.

In a case where the cartridge 200 is placed at a predetermined position on the support member 177, the shape of the support member 177 shown in FIG. 11A, and the shapes of the inner circumferential portion 177 b and the outer circumferential portion 177 d shown in FIG. 11B may not necessarily be round.

As shown in FIGS. 12A, 12B, the ventilator 350 is mounted on the rear surface of the casing 101 a of the body portion 101. The ventilator 350 is implemented as a fan. The ventilator 350 dissipates, to the outside of the analyzer 100, heat generated by the motor 171 mounted in the outer surface 154 of the housing unit 150. The bottom surface of the casing 101 a of the body portion 101 is distant from a setting surface by means of a leg portion over a predetermined distance. A ventilation opening 101 b is formed in the bottom surface at the front portion of the casing 101 a. By the ventilator 350 being driven, air taken in through the ventilation opening 101 b passes through the motor 171, and is discharged backward from the analyzer 100 as indicated by an outline arrow. Air taken in from the outside at a position of the ventilator 350 may pass through the motor 171, and may be discharged through the ventilation opening 101 b in the direction opposite to the direction indicated by the outline arrow.

In the planar view, that is, as viewed in the vertical direction, the outline of the body portion 101 is rectangular, and the outline of the motor 171 is also rectangular. The motor 171 is disposed in the body portion 101 such that the corner of the motor 171 and the corner of the body portion 101 are misaligned in the planar view. In the planar view, the detector 140 that includes the light detector 144 a is disposed in a space between the motor 171 and the corner of the body portion 101. Similarly, in the planar view, the magnet 120 and the movement mechanism 130 are disposed in a space between the motor 171 and another corner of the body portion 101. Thus, the shape of the body portion 101 in the planar view can be made compact, thereby reducing the size of the analyzer 100.

In the housing unit 150, the housings 152, 153 are formed for housing members disposed in the dark space 340. The housings 152, 153 are each shaped such that the outer side surface on the motor 171 side projects. The motor 171 is disposed lateral to the housing 152 so as to be spaced from the housing 152, and is disposed lateral to the housing 153 so as to be spaced from the housing 153. That is, the motor 171 is disposed in the outer surface 154. The motor 171 is thus disposed lateral to the housings 152, 153, whereby the analyzer 100 can be prevented from being increased in size in the height direction. The space is formed between the housing 152 and the motor 171, and the space is formed between the housing 153 and the motor 171. Therefore, the spaces allow convection of air to occur as shown in FIGS. 12A, 12B. Therefore, heat of the motor 171 can be effectively removed.

The housings 152, 153 are formed in the housing unit 150 so as to be spaced from each other. The motor 171 is disposed between the housing 152 and the housing 153. The ventilator 350 is disposed so as to oppose the space between the housings 152 and 153. Thus, air easily passes around the motor 171 through the space for the housings 152 and 153, whereby heat of the motor 171 can be effectively removed.

The ventilator 350 is disposed at a position as high as the motor 171 so as to oppose the motor 171. Specifically, as shown in FIG. 12B, the ventilator 350 is spaced by a predetermined distance from the motor 171 such that the position of the ventilator 350 and the position of the motor 171 overlap each other in the vertical direction. “Oppose” not only means that the rotation shaft of the ventilator 350 and the drive shaft of the motor 171 are parallel to each other, but also means that the rotation shaft of the ventilator 350 and the drive shaft of the motor 171 are orthogonal to each other as shown in FIG. 12A and FIG. 12B. Thus, air around the motor 171 is easily guided to the outside of the analyzer 100, whereby heat generated in the motor 171 can be efficiently exhausted. As described above, the motor 171 is disposed outside the dark space 340, and the ventilator 350 is also disposed outside the dark space 340. Thus, increase of the temperature in the dark space 340 can be effectively inhibited without interfering with light-shielding properties of the light-shielding portion that forms the dark space 340.

In Embodiment 1, the controller 301 described below drives, when receiving an instruction for starting analysis, the heaters 321, 322 to increase the temperature of the cartridge 200. At this time, the controller 301 controls the operation of the ventilator 350 on the basis of the temperature, of the cartridge 200, detected by the temperature sensor 178. For example, when the temperature of the cartridge 200 is lower than 40° C., the controller 301 causes the ventilator 350 to halt, and, when the temperature of the cartridge 200 is higher than 40° C., the controller 301 drives the ventilator 350. Thus, as compared to a case where the ventilator 350 is driven immediately after an instruction for starting analysis is received, a time period before the temperature of the cartridge 200 converges to 42° C., can be shortened, and power consumption of the ventilator 350 and the heaters 321, 322 can be reduced.

As shown in FIG. 13, the analyzer 100 includes the motors 135, 136, 161, 171, the encoder 172, the heaters 321, 322, the temperature sensors 331, 332, 178, the light detection unit 144, the ventilator 350, the imaging portion 193, the illumination portion 194, and the pressing portion 195, as described above. The analyzer 100 also includes the controller 301, a display unit 302, an input portion 303, a driving portion 304, and a sensor unit 305.

The controller 301 includes, for example, a processing unit and a storage unit. The processing unit includes, for example, a CPU, an MPU, and the like. The storage unit is implemented as, for example, a flash memory, a hard disk, or the like. The controller 301 receives signals from the components, respectively, of the analyzer 100, and controls the components of the analyzer 100. The display unit 302 and the input portion 303 are provided in, for example, a side surface portion of the body portion 101 or an upper surface portion of the lid portion 102. The display unit 302 is implemented as, for example, a liquid crystal panel. The input portion 303 is implemented as, for example, a button or a touch panel. The driving portion 304 includes another mechanism disposed in the analyzer 100. The sensor unit 305 includes a sensor for detecting a predetermined portion of the rotating cartridge 200, a sensor for detecting a mechanism moved to the position of an origination point by the motors 135, 136, 161, and another sensor disposed in the analyzer 100.

Next, an operation of the analyzer 100 will be described with reference to FIG. 14.

Firstly, an operator injects, through the opening 241, a blood specimen collected from a subject, and places the cartridge 200 on the support member 177. A test substance in the blood specimen includes, for example, an antigen. An example of the antigen is Hepatitis B surface antigen (HBsAg). The test substance may be one or more of an antigen, an antibody, and protein.

Predetermined reagents are stored in advance in the liquid storage portions 231, 232 and the chamber 211 of the cartridge 200. Specifically, an R1 reagent is stored in the liquid storage portion 231 positioned for the chamber 211 in the radial direction. An R2 reagent is stored in the chamber 211. An R3 reagent is stored in the liquid storage portion 231 positioned for the chamber 212 in the radial direction. Washing liquid is stored in the liquid storage portion 231 positioned for each of the chambers 213 to 215 in the radial direction. An R4 reagent is stored in the liquid storage portion 231 positioned for the chamber 216 in the radial direction. An R5 reagent is stored in the liquid storage portion 232.

In the following control, the controller 301 obtains a rotational position of the drive shaft 171 a of the motor 171 on the basis of an output signal from the encoder 172 connected to the motor 171. The controller 301 causes a sensor to detect a predetermined portion of the rotating the cartridge 200, to obtain a position of the cartridge 200 in the circumferential direction. Alternatively, the cartridge 200 may be placed at a predetermined position on the support member 177. Thus, the controller 301 allows each component of the cartridge 200 to be positioned at a predetermined position in the circumferential direction.

The controller 301 obtains positions of the mechanisms moved by the motors 135, 136, 161 on the basis of an output signal from the sensor for detecting the mechanism moved to the position of the originating point by the motors 135, 136, 161. Thus, the controller 301 allows the mechanisms moved by the motors 135, 136, 161, that is, the magnet 120 and the plate-shaped member 162 to be each positioned at a predetermined position.

In step S11, the controller 301 receives, through the input portion 303, an instruction for start from an operator, and starts step S12 and the following process steps.

In step S12, the controller 301 transfers plasma and the reagents into the chambers. Specifically, the controller 301 drives the motor 171 to rotate the cartridge 200, and drives the pressing portion 195 to press down the six seals 231 a positioned at positions opposing the pressing portion 195. The controller 301 drives the motor 171 to rotate the cartridge 200, and transfers the plasma positioned in the region 243 b, into the chamber 211, by a centrifugal force, and transfers, into the chambers 211 to 216, the reagents stored in the six liquid storage portions 231. Thus, the plasma, the R1 reagent, and the R2 reagent are mixed in the chamber 211. The R3 reagent is transferred into the chamber 212, the washing liquid is transferred into each of the chambers 213 to 215, and the R4 reagent is transferred into the chamber 216.

After the plasma and the reagents have been transferred in step S12, the controller 301 performs agitation. Specifically, the controller 301 drives the motor 171 so as to change between two different rotation speeds at predetermined time intervals while causing the motor 171 to rotate in a predetermined direction. For example, the controller 301 performs agitation by changing an electric current applied to the motor 171 at predetermined time intervals, or by switching the driving of the motor 171 between on and off at predetermined time intervals. Thus, an Euler force generated in the circumferential direction is varied at predetermined time intervals, whereby liquid in each of the chambers 211 to 216 is agitated. This agitation is performed not only in step S12 but also in steps S13 to S18 similarly after transfer.

The controller 301 may perform agitation by changing a rotating direction of the motor 171 at predetermined time intervals. However, when the motor 171 is driven in this manner, load on the motor 171 is increased. Therefore, as described above, the motor 171 is preferably driven so as to change between two rotation speeds while the motor 171 is caused to rotate in a predetermined direction.

The R1 reagent includes a capture substance that binds to the test substance. The capture substance includes, for example, an antibody that binds to the test substance. The antibody is, for example, a biotin-bound HBs monoclonal antibody. The R2 reagent includes magnetic particles in a liquid component. The magnetic particles are, for example, streptavidin-bound magnetic particles the surfaces of which are coated with avidin. In step S12, the plasma, the R1 reagent, and the R2 reagent are mixed and agitated, whereby the test substance and the R1 reagent bind to each other by antigen-antibody reaction. By reaction between antigen-antibody reaction product and the magnetic particles, the test substance bound to the capture substance in the R1 reagent binds to the magnetic particles by means of the capture substance. Thus, a complex in which the test substance and the magnetic particles bind to each other, is generated.

Next, in step S13, the controller 301 causes the complex in the chamber 211 to be transferred from the chamber 211 into the chamber 212. Thus, the complex generated in the chamber 211 and the R3 reagent are mixed with each other in the chamber 212. The R3 reagent includes a labeling substance. The labeling substance includes: a capture substance that specifically binds to the test substance; and a label for chemiluminescence. For example, the labeling substance is a labelled antibody which includes an antibody used as the capture substance. In step S13, the complex generated in the chamber 211 and the R3 reagent are mixed and agitated, so that the complex generated in the chamber 211 and the labelled antibody contained in the R3 reagent react with each other. Thus, a complex in which the test substance, the capture antibody, the magnetic particles, and the labelled antibody are bound, is generated.

The process step of step S13 will be described in detail with reference to FIG. 15. FIG. 15 is a flow chart showing step S13 in FIG. 14 in detail. In the following description, FIG. 15 is mainly referred to, and FIG. 16A to FIG. 17C showing state transitions are referred to as appropriate.

When the process step of step S12 has ended, the complex spreads in the chamber 211 as shown in FIG. 16A. In step S101, the controller 301 drives the movement mechanism 130 to cause the magnet 120 to move close to the cartridge 200, thereby collecting the complex that spreads in the chamber 211, as shown in FIG. 16B. At this time, in the horizontal plane, the controller 301 causes the tip portion 122 a of the magnet 120 to move close to a region that is at the center, in the circumferential direction, of the chamber 211, and that is close to the outer side, in the radial direction, of the chamber 211.

In Embodiment 1, an amount of mixture, in the chamber 211, which contains the complex is less than the total capacity of the chamber 211. If the amount of the mixture stored in the chamber 211 is less than the total capacity of the chamber 211, it is assumed that an amount of mixture varies among regions in the chamber 211. However, in a case where the test substance, the R1 reagent, and the R2 reagent are mixed in the chamber 211, and a centrifugal force is thereafter applied to the chamber 211 in the agitation, as described above, the mixture is unevenly distributed in an outer side portion in the chamber 211 at any time. Accordingly, in a case where the complex in the chamber 211 is collected by the magnet 120, when the tip portion 122 a of the magnet 120 is positioned in a storage region of the mixture that is unevenly distributed in the chamber 211, that is, positioned in a region closer to the outer side of the chamber 211, the complex in the mixture in the chamber 211 can be assuredly collected at the position of the magnet 120.

An amount of the mixture, in each of the chambers 212 to 215, which contains the complex is also less than the total capacity of the corresponding chamber of the chambers 212 to 215. Therefore, similarly to the case for the chamber 211, when the magnet 120 is positioned in the region closer to the outer side, the complex in the mixture in each of the chambers 212 to 215 can be assuredly collected at the position of the magnet 120.

In step S102, the controller 301 drives the movement mechanism 130 to move the magnet 120 so as to be closer to the rotation shaft 311, and causes the complex to be transferred to the connecting portion between the region 222 that connects to the chamber 211, and the region 221, as shown in FIG. 16C. In step S102, the speed at which the complex is moved relative to the cartridge 200 is preferably lower than or equal to 10 mm/second so as to prevent the complex from being left in the chamber 211. Specifically, for example, the speed is 0.5 mm/second. The magnet 120 is moved by the movement mechanism 130 such that the speed at which the complex is moved can be as described above.

In step S103, the controller 301 drives the motor 171 to rotate the cartridge 200, and causes the complex to be transferred to the connecting portion between the region 221, and the region 222 that connects to the chamber 212, as shown in FIG. 17A. In step S103, the speed at which the complex is moved relative to the cartridge 200 is also set similarly as in step S102. The cartridge 200 is rotated by the motor 171 such that the speed at which the complex is moved can be as described above.

In step S104, the controller 301 drives the movement mechanism 130 to move the magnet 120 so as to be distant from the rotation shaft 311, and causes the complex to be transferred into the chamber 212, as shown in FIG. 17B. In step S104, the speed at which the complex is moved relative to the cartridge 200 is set similarly as in step S102. In step S105, the controller 301 drives the movement mechanism 130 to move the magnet 120 so as to be distant from the cartridge 200, and causes the complex to spread in the chamber 212, as shown in FIG. 17C.

As described above, in steps S101 to S105, the controller 301 causes the magnet 120 to move close to the cartridge 200 at a position opposing the chamber 211, and thereafter causes the magnet 120 to move along the channel 220 while the magnet 120 is maintained close to the cartridge 200, and causes the magnet 120 to be positioned at a position opposing the chamber 212. Thereafter, the controller 301 causes the magnet 120 to move so as to be distant from the cartridge 200, and cancels magnetic collection of the complex by the magnet 120. Thus, the complex can be assuredly prevented from being left in the chamber 211 and the channel 220.

In step S106, the controller 301 performs control so as to perform the above-described agitation. At this time, the magnetic collection of the complex is cancelled before the agitation, and the complex spreads in the chamber 212, thereby assuredly agitating the liquid in the chamber 212.

As described above, the process step of step S13 in FIG. 14 is performed. The transfer and agitation shown in steps S101 to S106 are performed similarly also in steps S14 to S17 described below.

Returning to FIG. 14, in step S14, the controller 301 causes the complex in the chamber 212 to be transferred from the chamber 212 into the chamber 213. Thus, in the chamber 213, the complex generated in the chamber 212 and washing liquid are mixed. In step S14, by the complex generated in the chamber 212 and washing liquid being mixed and agitated, the complex and unreacted substances are separated from each other in the chamber 213. That is, in the chamber 213, the unreacted substances are removed by washing.

In step S15, the controller 301 causes the complex in the chamber 213 to be transferred from the chamber 213 into the chamber 214. Thus, in the chamber 214, the complex generated in the chamber 212 and washing liquid are mixed. Also in the chamber 214, unreacted substances are removed by washing.

In step S16, the controller 301 causes the complex in the chamber 214 to be transferred from the chamber 214 into the chamber 215. Thus, in the chamber 215, the complex generated in the chamber 212 and washing liquid are mixed. Also in the chamber 215, unreacted substances are removed by washing.

In step S17, the controller 301 causes the complex in the chamber 215 to be transferred from the chamber 215 into the chamber 216. Thus, in the chamber 216, the complex generated in the chamber 212 and the R4 reagent are mixed. The R4 reagent is a reagent for dispersing the complex generated in the chamber 212. The R4 reagent is, for example, a buffer. In step S17, the complex generated in the chamber 212 and the R4 reagent are mixed and agitated, whereby the complex generated in the chamber 212 is dispersed.

In step S18, the controller 301 causes the R5 reagent to be transferred into the chamber 216. Specifically, the controller 301 drives the motor 171 to rotate the cartridge 200, and drives the pressing portion 195 to press down the seal 232 a positioned at a position opposing the pressing portion 195. The controller 301 drives the motor 171 to rotate the cartridge 200, and causes the R5 reagent stored in the liquid storage portion 232 to be transferred into the chamber 216 by a centrifugal force. Thus, in the chamber 216, the R5 reagent is further mixed with the mixture generated in step S17.

The R5 reagent is a luminescent reagent containing a luminescent substrate that generates light by reaction with the labelled antibody bound to the complex. In step S18, the mixture generated in step S17 and the R5 reagent are mixed and agitated, to prepare a sample. The sample causes chemiluminescence by reaction between the luminescent substrate and the labeling substance bound to the complex. Specifically, when molecules excited, by chemical reaction between the labeling substance and the luminescent substrate, into an excited state are returned from the excited state to a ground state, light is emitted. According to an electrochemiluminescence method, by the labeling substance being electrochemically stimulated, chemiluminescence may be caused to occur. The chemiluminescence may be caused to occur by the LOCI (luminescent oxygen channeling immunoassay). The bioluminescence by luciferin/luciferase may be caused to occur as chemiluminescence.

In step S19, the controller 301 drives the motor 171 to position the chamber 216 vertically above the light detector 144 a, and causes the light detector 144 a to detect light generated from the chamber 216. In step S20, the controller 301 performs immune analysis on the basis of the light detected by the light detector 144 a. The light detector 144 a outputs a pulse waveform based on reception of photons. The light detection unit 144 counts the photons at regular intervals on the basis of the output signal from the light detector 144 a and outputs the counted value. The controller 301 performs analysis for presence or absence of the test substance and an amount of the test substance on the basis of the counted value outputted by the light detection unit 144, and causes the display unit 302 to display the result of the analysis.

As described above, the complex is transferred sequentially into the chambers 211 to 216. In a case where the complex is transferred through the plurality of the chambers, the complex is likely to be left in the chambers 211 to 215 and the channel 220. However, in a case where the complex is assuredly transferred by using the magnet 120 as described above, the complex can be assuredly prevented from being left therein. Thus, unintended reduction of an amount of light detected by the light detector 144 a can be inhibited. Therefore, false-negative due to the unintended reduction of an amount of light can be inhibited, thereby allowing highly accurate detection.

The magnetic particles may be any particles that contain a magnetic material as a base and are used for standard immunoassay. For example, the magnetic particles containing, as the base, Fe₂O₃ and/or Fe₃O₄, cobalt, nickel, ferrite, magnetite, or the like, can be used. The magnetic particles may be coated with a binding substance for binding to a test substance, or may bind to a test substance by means of a capture substance for binding the magnetic particles and the test substance to each other. The capture substance is an antigen, an antibody, or the like that binds the magnetic particles and the test substance mutually to each other.

The labeling substance contains a label for chemiluminescence and a capture substance that specifically binds to a test substance. The capture substance is not particularly limited, and may be a substance that specifically binds to a test substance. In Embodiment 1, the capture substance binds to a test substance by antigen-antibody reaction. More specifically, in Embodiment 1, the capture substance is an antibody. When the test substance is an antibody, the capture substance may be an antigen of the antibody. When the test substance is a nucleic acid, the capture substance may be a nucleic acid that is complementary to the test substance. Examples of the label for the chemiluminescence include enzymes such as alkaline phosphatase (ALP), peroxidase, glucose oxidase, tyrosinase, and acid phosphatase. When chemiluminescence is electrochemiluminescence, the label is not particularly limited, and may be a substance that emits light by electrochemical stimuli. Examples of the label include a ruthenium complex.

When the label is an enzyme, a luminescent substrate for the enzyme may be appropriately selected from known luminescent substrates according to the enzyme to be used. Examples of the luminescent substrate include luminol-based luminescent substrates and dioxetane-based luminescent substrates. When the enzyme is alkaline phosphatase, examples of the luminescent substrate include: chemiluminescent substrates such as CDP-Star (registered-trademark), (disodium 4-chloro-3-(methoxyspiro[1,2-dioxetane-3,2′-(5′-chloro)tricyclo[3.3.1.13,7]decane]-4-yl)phenylphosphate), and CSPD (registered-trademark) (disodium 3-(4-methoxyspiro[1,2-dioxetane-3,2-(5′-chloro)tricyclo[3.3.1.13,7]decane]-4-yl)phenylphosphate); and luminescent substrates such as p-nitrophenyl phosphate, 5-bromo-4-chloro-3-indolyl phosphate (BCIP), 4-nitro blue tetrazolium chloride (NBT), and iodonitrotetrazolium (INT).

Next, verification by the inventors as to whether or not the dark space 340 is appropriately formed by the light-shielding portion, that is, whether or not light transmitted into the dark space 340 is appropriately blocked by the light-shielding portion, will be described.

The inventors firstly performed calculation of a required dark count value in the case of light generated from a sample for a predetermined measurement item being detected separately from light generated by a reference sample containing no test substance. The calculation described below was performed according to a 3SD method.

As shown in FIG. 18, in the case of measurement being performed for the predetermined measurement item, LOD_(ave) represents an average counted value, and SD_(LOD) represents the standard deviation thereof. In the case of measurement being performed for a calibrator C0 that is a reference sample containing no test substance, C0_(ave) represents an average counted value, and SD_(C0) represents the standard deviation thereof. N represents a counted value based on light having leaked into the dark space 340, that is, a dark count value, and SD_(d) represents the standard deviation thereof. SD_(d) can be represented as (N/N^(1/2))=N^(1/2).

In a case where measurement for the predetermined measurement item and measurement for the calibrator C0 are performed, a counted value obtained by the measurement for the predetermined measurement item needs to be greater than a counted value obtained by the measurement for the calibrator C0. In a case where this is represented by an expression in consideration of variation in counted value in the measurement and influence of the dark count value N, the following conditional expression (1) is obtained.

[Expression 1]

(LOD _(ave)−3√{square root over (SD _(LOD) ² +N)})−(C0_(ave)+3√{square root over (SD _(C0) ² +N)}>0  (1)

In other words, the conditional expression (1) indicates that the value of X shown in FIG. 18 needs to be greater than 0. Referring to the conditional expression (1), as the dark count value N is reduced, the conditional expression (1) is satisfied well even if the value of LOD_(ave) is small. That is, it can be found that the minimal detection density can be set such that the less the dark count value N is, the lower the minimal detection density is.

Subsequently, the inventors put, in the conditional expression (1), values of assumption examples 1, 2 in which measurement by an actual apparatus was assumed, to calculate a condition for the dark count value N.

In assumption example 1, “TSH” as a measurement item based on chemiluminescence was assumed, and 219 was assigned to LOD_(ave), 22 that was 10% of LOD_(ave) was assigned to SD_(LOD), 70 was assigned to C0_(ave), and 7 that was 10% of C0_(ave) was assigned to SD_(C0). As a result, in assumption example 1, N≦372/(mm²·sec.) was obtained as a condition for the dark count value N. Therefore, it can be said that, for the measurement item “TSH”, when N≦372/(mm²·sec.) is satisfied, the measurement can be appropriately performed.

Meanwhile, in assumption example 2, a measurement item in the case of light generated by chemiluminescence being lower than that in assumption example 1, was assumed. That is, in assumption example 2, 150 was assigned to LOD_(ave), and 15 that was 10% of LOD_(ave) was assigned to SD_(LOD). C0_(ave) and SD_(C0) were the same as those in assumption example 1. As a result, in assumption example 2, N≦53/(mm²·sec.) was obtained as a condition for the dark count value N. Therefore, it can be said that, for the measurement item in assumption example 2, when N≦53/(mm²·sec.) is satisfied, the measurement can be appropriately performed.

Subsequently, the inventors actually measured a counted value of photons based on an output signal from the light detector 144 a in the case of no light being generated in the dark space 340, that is, measured a dark count value N, by using an actual apparatus based on the analyzer 100, in a normal use environment. As a result, 4.0/(mm²·sec.) was obtained as the dark count value N.

The above-described verifications indicate that the dark count value N obtained by using the actual apparatus based on the analyzer 100 satisfies the conditions for both assumption examples 1 and 2 in which actual measurement was assumed. Therefore, it is found that, in the analyzer 100, the dark space 340 that can be sufficiently used for actual measurement can be formed.

Subsequently, study, by the inventors, of heat generation of the motor will be described.

FIG. 19A illustrates a table that collectively indicates operation times of the motors used in the analyzer 100.

“Until transfer of reagent in first measurement” represents a time period T1 during which the analyzer 100 receives an instruction for start in step S11, an injected blood specimen is separated into blood cells and plasma in the separator 242, centrifugal force is applied in step S12 shown in FIG. 14, and transfer of plasma, the R1 reagent, washing liquid, and the R4 reagent into the chambers 211 to 216 is completed. “Until agitation of R4 reagent” represents a time period T2 during which agitation is started in step S12, and a complex is transferred into the chamber 216 and the agitation is completed in step S17. “Until detection” represents a time period T3 from completion of agitation in step S17 to completion of light detection in step S19. “Total time period” represents a length of each time period. In each time period, “operation time of motor” represents a time in which the motor is excited for driving. The unit of the time is “minute” in all of the cells.

According to the table shown in FIG. 19A, the total of the operation times of the motor 171 is 10.4 minutes, the total of the operation times of the motors 135, 136 is 5.0 minutes, and the total of the operation times of the motor 161 is 0.02 minutes. The proportion of the operation times of the motor 171 to the total time period of 21.5 minutes is 48.4%, the proportion of the operation times of the motors 135, 136 to the total time period of 21.5 minutes is 23.3%, and the proportion of the operation times of the motor 161 to the total time period of 21.5 minutes is 0.1%. The wattage of the motor 171 is 24V×1.5 A when the electric current is maximum, the wattage of each of the motors 135, 136 is 24V×0.5 A when the electric current is maximum, and the wattage of the motor 161 is 24V×0.3 A when the electric current is maximum.

According to the operation times and operation proportions shown in FIG. 19A, and the wattage of each motor, it is found that heat generation of the motor 171 is highest. However, in the configuration of Embodiment 1, since the motor 171 having the highest heat generation is disposed outside the dark space 340, increase of heat in the dark space 340 can be inhibited, and the temperature in the dark space 340 can be stabilized.

Subsequently, verification, by the inventors, for temperature change in the case of the motor being disposed inside the dark space will be described. The verification was performed by using a prototype of the analyzer 100. In the prototype of the analyzer 100, a motor, a cartridge, a light detector, and the like for verification were placed in the dark space, and a temperature sensor was set on a heat block on which the cartridge was placed. The cartridge was placed on the heat block and the temperature detected by the temperature sensor was thus almost equal to the temperature of the cartridge. An ambient temperature of the prototype of the analyzer 100 was set to 40° C. In verification example 1, excitation of the motor was constantly set to be off. In verification example 2, excitation of the motor was constantly set to be on.

As shown in FIG. 19B, in verification example 1, since the excitation of the motor was off, the temperature of the cartridge was not substantially increased. Meanwhile, in verification example 2, since the excitation of the motor was on, the temperature of the cartridge continued to increase with the elapse of time. These results indicate that, in a case where a motor is disposed inside the dark space, and the motor is frequently used, the temperature of the cartridge is increased, and it is difficult to stabilize the temperature in the dark space. The motor used for the verifications was smaller than the motor 171 of Embodiment 1. Therefore, in a case where the motor 171 is used, the increase of the temperature may become greater in verification example 2. Therefore, as in Embodiment 1, it is important to dispose the motor 171 outside the dark space 340 for inhibiting the temperature of the cartridge 200 from increasing.

Even in a case where a motor smaller than the motor 171 of Embodiment 1 is used, when a time period for which the motor is excited is longer than or equal to five minutes, the graph in verification example 1 and the graph in verification example 2 start to deviate from each other. Therefore, it is particularly advantageous that the motor 171 is disposed outside the dark space 340 as in Embodiment 1 in a case where the motor is excited for five minutes or longer in one measurement. In Embodiment 1, as shown in FIG. 19A, since the operation time of the motor 171 is 10.4 minutes, it is particularly advantageous that the motor 171 is disposed outside the dark space 340.

Subsequently, verification, by the inventors, for the effect of the ventilator 350 will be described. The verification was performed by actually using the analyzer 100.

In the verification, when the verification was started, excitation of the motors 135, 136, 161, 171 was started, and driving of the ventilator 350 was started. Also after those, the excitation of each motor and the driving of the ventilator 350 were continuously performed. In a time period T during the verification, only driving of the ventilator 350 was temporarily halted. While each motor and the ventilator 350 were thus controlled, the temperatures were measured on the inner side in the radial direction of the upper surface of the cartridge 200, on the outer side in the radial direction of the upper surface of the cartridge 200, in the motor 171, outside the analyzer 100, and around the cartridge 200. The analyzer 100 was set in a constant-temperature bath, and the temperature in the constant-temperature bath was set to 35° C. The heaters 321, 322 were controlled such that the temperature of the cartridge 200 was 42° C.

FIG. 20A shows a state where the temperature measured at each portion changed with the elapse of time in the verification. FIG. 20B shows the temperature change in a range of 30° C. to 55° C., and, in FIG. 20B, the temperature change outside the analyzer 100 shown in FIG. 20A is not shown.

As shown in FIG. 20A, the temperature of the motor 171 was greatly increased from the start. However, since the motor 171 was disposed outside the light-shielding portion as described above, the increase of the temperature in the analyzer was inhibited such that the temperature in the analyzer was about 42° C. According to the result shown in FIG. 20A, it is found that it is important to dispose the motor 171 outside the light-shielding portion in order to inhibit increase of the temperature, in the analyzer 100. As shown in FIG. 20B, the temperature on the inner side of the cartridge 200 is slightly higher than the temperature on the outer side of the cartridge 200. This may be because the temperature of the motor 171 is more easily conducted through the rotation shaft 311 onto the inner side of the cartridge 200 than onto the outer side of the cartridge 200.

As shown in FIG. 20B, in the time period T during which driving of the ventilator 350 was halted, the temperature around the cartridge 200 was suddenly increased. This may be because, since cooling of the motor 171 by the ventilator 350 was halted, heat of the motor 171 was not dissipated to the outside of the analyzer 100, and the heat that was not dissipated was transmitted into the dark space 340. At this time, the temperature of the cartridge 200 was gently increased according to the temperature around the cartridge 200 being suddenly increased. In the verification, when about 15 minutes elapsed since halting of driving of the ventilator 350, the driving of the ventilator 350 was restarted. Thus, the temperature around the cartridge 200 was suddenly decreased, and the temperature of the cartridge 200 was also inhibited from being increased. According to the result shown in FIG. 20B, it is found that it is important to drive the ventilator 350 in order to inhibit increase of temperature.

In the analyzer 100, the 24V×1.5 A motor 171 is used in order to rotate the cartridge 200. However, depending on the wattage of the motor 171 or how often the cartridge 200 is rotated, heat generated from the motor 171 may not be as great as that shown in FIG. 20A. In such a case, the ventilator 350 may not necessarily be provided. That is, although, in the analyzer 100, the ventilator 350 is preferably used in order to inhibit increase of temperature, the ventilator 350 may be omitted depending on, for example, setting and driving of the motor 171.

Embodiment 2

In Embodiment 1, as described with reference to FIG. 2A, the lid portion 102 is opened, and the cartridge 200 is placed at the analyzer 100. In Embodiment 2, as shown in FIG. 21A, the cartridge 200 is placed into an analyzer 400 by using a tray 402 that is movable to the outside through a hole 401 a formed in the front surface of a casing 401 of the analyzer 400.

A light-shielding member 403 is mounted at the front end of the tray 402. The outer shape of the light-shielding member 403 is slightly greater than the hole 401 a. An elastic member 404 having light-shielding properties is mounted near the outlet of the hole 401 a. When the tray 402 is moved inward, the hole 401 a is closed by the light-shielding member 403 and the elastic member 404. The other components of the analyzer 400 are substantially the same as described in specific example of structure for the analyzer 100 in Embodiment 1.

Also in Embodiment 2, similarly to Embodiment 1, the complex can be assuredly transferred, whereby accuracy for analyzing a test substance by the analyzer 400 can be maintained high. A dark space into which light does not come from the outside can be formed in the analyzer 400, whereby accuracy for detecting a test substance can be enhanced.

Embodiment 3

In Embodiment 3, as shown in FIG. 21B, a support member 510 is disposed instead of the support member 177, and a cartridge 520 is used instead of the cartridge 200. The other components are the same as described in specific example of structure in Embodiment 1.

The support member 510 includes a hole 511 and three placement portions 512. The hole 511 is formed at the center of the support member 510. The support member 510 is mounted to the rotation shaft 311 through a predetermined member. Thus, the support member 510 can be rotated about the rotation shaft 311. The three placement portions 512 are provided in the circumferential direction. Each placement portion 512 has a surface 512 a and a hole 512 b. The surface 512 a is formed so as to be one level lower than the upper surface of the support member 510. The hole 512 b is formed at the center of the surface 512 a, and penetrates through the support member 510 in the up-down direction. The cartridge 520 has a rectangular shape, and has the same structure as the cartridge 200.

When analysis is started, an operator injects a blood specimen into the cartridge 520, and places the cartridge 520 on the placement portion 512, as in the case of the cartridge 200 being used. As in Embodiment 1, the controller 301 drives the motor 171, the movement mechanism 130, and the detector 140. Thus, as in Embodiment 1, the complex in the cartridge 520 is assuredly transferred by the magnet 120. Therefore, as in Embodiment 1, accuracy for analyzing a test substance by the analyzer 100 can be maintained high. In Embodiment 3, the cartridges 520 can be placed on the three placement portions 512, respectively, whereby analysis can be performed simultaneously with the three cartridges 520.

Embodiment 4

In Embodiment 1, as shown in FIG. 1A, the light receiving unit 70 is disposed inside the dark space 81. However, the light receiving unit 70 may be disposed such that a part of the light receiving unit 70 is disposed inside the dark space 81 and another part of the light receiving unit 70 is disposed outside the dark space 81.

FIG. 22A shows an exemplary case where the light receiver 70 a is disposed inside the dark space 81, and a circuit unit 70 c of the light receiving unit 70 is disposed outside the dark space 81. In the example shown in FIG. 22A, among the components of the light receiving unit 70, the light receiver 70 a that includes the light receiving surface 70 b is disposed inside the dark space 81. FIG. 22B shows an exemplary case where, in FIG. 22A, a hole is formed in the light-shielding portion 80 that forms the dark space 81 and the light receiver 70 a is disposed on the outer side portion of the hole. In the example shown in FIG. 22B, among the components of the light receiving unit 70, only the light receiving surface 70 b is disposed inside the dark space 81. In both the cases shown in FIG. 22A and FIG. 22B, the light receiving surface 70 b is disposed inside the dark space 81. Therefore, also in these cases, light from the outside can be inhibited from reaching the light receiving surface 70 b.

In the examples shown in FIG. 22A and FIG. 22B, in a case where, similarly to specific example of structure in Embodiment 1, the liquid storage portion and the seal are provided in the cartridge 20, a pressing portion 90 corresponding to the pressing portion 195 is disposed inside the dark space 81 as shown in FIG. 23A and FIG. 23B. Also in these cases, the pressing portion 90 includes a pin member 91 for pressing the seal of the cartridge 20 from thereabove. The support member 31 is provided so as to extend from the rotation shaft 32 side to a position opposing the pin member 91 of the pressing portion 90 across the cartridge 20. Thus, also in the examples shown in FIG. 23A and FIG. 23B, even if pressing force is applied to the cartridge 20 by the pressing portion 90, the support member 31 acts as a base and supports the cartridge 20. Therefore, in the opening of the seals, displacement or damage may be inhibited from occurring in the cartridge 20. Therefore, in the opening of the seals, reduction of measurement accuracy is inhibited.

Embodiment 5

In Embodiment 1, as shown in FIG. 2B, the chambers 211 to 216 each have a round shape. Meanwhile, in Embodiment 5, the chambers 211 to 216 each have a shape shown in FIG. 24A. The other components are the same as described in specific example of structure in Embodiment 1.

FIGS. 24B, 24C are each an enlarged view of a chamber 213 shown in FIG. 24A. In FIGS. 24A to 24C, the hole 201 of the cartridge 200 is positioned on the X-axis positive side of the chamber 213. That is, the rotation shaft 311 is positioned on the X-axis positive side of the chamber 213. The structures of the chambers 211, 212, and 214 to 216 are the same as the structure of the chamber 213, and the structure and the effect of the chamber 213 will be described.

As shown in FIG. 24B, the chamber 213 is shaped so as to be symmetric about the extension of the diameter of the rotation shaft 311. The chamber 213 is connected to the channel 220 on the rotation shaft 311 side. The chamber 213 includes protrusions 213 b that protrude toward the rotation shaft 311 on both sides that sandwich a connecting position 213 a connecting to the channel 220. In other words, the chamber 213 has the protrusions 213 b that protrude in the X-axis direction, on the Y-axis positive side and the Y-axis negative side of the connecting position 213 a. Each protrusion 213 b is formed as a curved surface that protrudes toward the rotation shaft 311. An angle α between: the extension from the end portion on the connecting position 213 a side of the protrusion 213 b; and the extension, of the diameter of the rotation shaft 311, which passes through the center of the connecting position 213 a, is less than 90°.

The chamber 213 has planar wall surfaces 213 c connected to the protrusions 213 b on both sides, respectively, which sandwich the connecting position 213 a. The wall surfaces 213 c connect to the end portions disposed on sides opposite to the connecting position 213 a sides of the protrusions 213 b. Specifically, each wall surface 213 c extends in the radial direction as viewed in the Z-axis direction, that is, extends in the X-axis direction. The chamber 213 has, between the two protrusions 213 b, a projection 213 d that projects toward the rotation shaft 311. The channel 220 is connected to the projection 213 d. The chamber 213 has an inner wall 213 e disposed so as to be distant from the rotation shaft 311 in the radial direction. The inner wall 213 e is arc-shaped as viewed in the Z-axis direction.

When the chamber 213 is structured as described above, the following effect is exhibited.

Also when, as described above, the cartridge 200 is rotated, and liquid in the chamber 213 is agitated by using a centrifugal force and Euler force, the two protrusions 213 b act as barriers, and the liquid in the chamber 213 can be inhibited from entering the connecting position 213 a connecting to the channel 220. That is, even if the liquid is moved in the chamber 213 by agitation, the leading end portion of the liquid in the chamber 213 is held in the chamber 213 by the protrusions 213 b as shown in FIG. 24C. Thus, the liquid in the chamber 213 can be inhibited from entering the channel 220 during agitation.

Even if liquid in the chamber 213 is greatly oscillated during agitation, the liquid in the chamber 213 is received by the protrusion 213 b as shown in FIG. 24C, and the liquid is inhibited from further moving along the inner wall of the chamber 213. As shown in FIG. 24D, if the chamber 213 does not have the protrusions 213 b, the liquid in the chamber 213 moves along the inner wall, and the leading end portion of the liquid in the flowing direction is curved in the X-axis negative direction by a centrifugal force as indicated by a dashed arrow, and hits against another portion of the liquid. In this case, the liquid bubbles due to the hitting of the liquid. However, as shown in FIG. 24C, when the protrusions 213 b are formed in the chamber 213, the liquid in the chamber 213 is inhibited from moving forward along the inner wall, so that bubbling in the chamber 213 during agitation can be inhibited.

Thus, in a case where the liquid is inhibited from entering the channel 220 and bubbling during the agitation, the magnetic particles in the chamber 213 can be moved to the following chamber without leaving the magnetic particles therein, whereby detection can be appropriately performed.

In a case where liquid is inhibited from entering the channel 220 and bubbling during agitation, a rotation speed of the cartridge 200 during agitation can be increased, and a degree of freedom for changing the rotation speed can be enhanced. Meanwhile, in a case where the rotation speed is thus controlled, heat generation from the motor 171 is increased. However, since the motor 171 is disposed outside the dark space 340 as described above, even when heat generation from the motor 171 is increased, unstabilization of the temperature in the dark space 340 can be inhibited, and the measurement can be appropriately performed.

The chamber 213 has the planar wall surfaces 213 c. Thus, when liquid is moved onto the wall surface 213 c during agitation, change of the flow of the liquid can be increased as compared to a case where the wall surface is curved. Therefore, the liquid in the chamber 213 can be effectively agitated. As shown in FIG. 24D, when the wall surface is curved, the leading end portion of the liquid in the flowing direction is curved and is likely to hit against another portion of the liquid. However, since the wall surfaces 213 c are formed so as to be planar, the state as shown in FIG. 24D can be inhibited from occurring. Therefore, liquid in the chamber 213 can be inhibited from bubbling during agitation.

Although the wall surfaces 213 c are formed so as to extend in the radial direction, the wall surfaces 213 c may extend so as to be tilted relative to the radial direction. However, in a case where the two wall surfaces 213 c are tiled relative to the radial direction such that the end portions on the X-axis positive side are close to each other, although the liquid in the chamber 213 can be more effectively agitated, hitting in the liquid is likely to occur similarly as in the case shown in FIG. 24D. In a case where the two wall surfaces 213 c are tilted relative to the radial direction such that the end portions on the X-axis positive side are distant from each other, although hitting in the liquid is less likely to occur, the liquid agitating effect in the chamber 213 is lowered. Therefore, as shown in FIG. 24B, the two wall surfaces 213 c are preferably formed so as to extend in the radial direction.

Even if liquid in the chamber 213 is greatly oscillated and flows over the protrusion 213 b during agitation, the liquid that flows thereover is received by the projection 213 d, and is less likely to enter the channel 220. As shown in FIG. 24E, in a case where the chamber 213 does not have the projection 213 d, liquid that is greatly oscillated may enter the channel 220 as indicated by a dashed arrow. However, when the chamber 213 has the projection 213 d, the liquid in the chamber 213 can be assuredly inhibited from entering the channel 220 during agitation.

Each protrusion 213 b is formed as a curved surface that protrudes toward the rotation shaft 311. Therefore, the magnetic particles can be inhibited from being left in the protrusions 213 b during agitation. Thus, the magnetic particles in the chamber 213 can be moved into the following chamber without leaving the magnetic particles behind. The chamber 213 is shaped so as to be symmetric about the diameter of the rotation shaft 311. Therefore, in both the Y-axis positive direction and the Y-axis negative direction, liquid can be inhibited from flowing into the channel 220 and bubbling. Since the angle α shown in FIG. 24B is less than 90°, the end portion of the protrusion 213 b on the connecting position 213 a side acts as a barrier, and liquid is assuredly inhibited from flowing into the channel 220 and bubbling during agitation.

The shape of the chamber 213 is not limited to the shape shown in FIG. 24B, and may be another shape. For example, the chamber 213 may have a shape as shown in any of FIGS. 25A to 25C.

In the chamber 213 shown in FIG. 25A, a straight line portion 213 f is formed between each protrusion 213 b and the projection 213 d as compared to the structure shown in FIG. 24B. In this case, liquid received by the protrusion 213 b is likely to flow toward the projection 213 d along the straight line portion 213 f due to surface tension. Therefore, as shown in FIG. 24B, the protrusions 213 b and the projection 213 d are preferably formed so as to be continuous with each other.

In the chamber 213 shown in FIG. 25B, the protrusions 213 b and the wall surfaces 213 c are omitted as compared to the structure shown in FIG. 24B. In this case, when liquid in the chamber 213 is oscillated, the liquid in the chamber 213 is likely to enter the channel 220 as compared to the structure shown in FIG. 24B. However, as compared to the structure shown in FIG. 24E, the projection 213 d is provided, and, thus, the liquid in the chamber 213 is less likely to enter the channel 220.

In the chamber 213 shown in FIG. 25C, a protrusion 213 g is further provided between the projection 213 d and the protrusion 213 b on the Y-axis positive side as compared to the structure shown in FIG. 24B. The protrusion 213 g is connected to, for example, a flow path that allows air to pass therethrough, or a flow path other than the channel 220. When the structure shown in FIG. 25C is applied to the chamber 211, the projection 213 d is connected to the channel 220 and the protrusion 213 g is connected to the region 243 b.

In the chamber 213 shown in FIG. 24B, a flow path that allows air to pass therethrough, or a flow path other than the channel 220 may be connected to the projection 213 d. When the other flow path is connected to the projection 213 d, forming of the cartridge 200 can be facilitated as compared to a case where the other flow path is connected to the region 222 of the channel 220.

Embodiment 6

In Embodiment 1, the liquid storage portions 231, 232 are each provided with the seal at only one position in the radial direction. Meanwhile, in Embodiment 6, the liquid storage portions 231, 232 are each provided with the seals at two different positions in the radial direction. Specifically, as shown in FIG. 26A, seals 231 a, 231 b are provided on the upper surfaces on the inner side and the outer side, respectively, in the radial direction, of the liquid storage portion 231. Seals 232 a, 232 b are provided on the upper surfaces on the inner side and the outer side, respectively, in the radial direction, of the liquid storage portion 232. In Embodiment 6, the pressing portion 195 is structured as shown in FIG. 26B to FIG. 27B. The other components in Embodiment 6 are the same as described in specific example of structure in Embodiment 1.

In Embodiment 6, when a reagent stored in the liquid storage portion 231 is transferred into a chamber disposed on the outer side of the liquid storage portion 231, the controller 301 firstly drives the motor 171 to rotate the cartridge 200, and causes the reagent in the liquid storage portion 231 to be positioned on the outer circumferential side in the liquid storage portion 231 by a centrifugal force. Subsequently, the controller 301 drives the pressing portion 195 to open the seal 231 b positioned on the outer side of the liquid storage portion 231. Thus, the inside of the liquid storage portion 231 and the channel 220 are connected to each other. Subsequently, the controller 301 drives the pressing portion 195 to open the seal 231 a positioned on the inner side of the liquid storage portion 231. Thus, the inner circumferential side portion of the liquid storage portion 231 and the outside of the cartridge 200 are connected to each other. The controller 301 drives the motor 171 to rotate the cartridge 200, and causes the reagent in the liquid storage portion 231 to be transferred into a chamber positioned on the outer side of the liquid storage portion 231 by a centrifugal force.

Also when the reagent stored in the liquid storage portion 232 is transferred into the chamber 216, the controller 301 performs the process similar to that described above. That is, the controller 301 causes the cartridge 200 to be rotated, causes the seal 232 b to be opened, causes the seal 232 a to be opened, and causes the cartridge 200 to be rotated in order, respectively.

In Embodiment 6, the reagent in the liquid storage portion 231 is enclosed in the liquid storage portion 231 by the seals 231 a, 231 b, and the reagent in the liquid storage portion 232 is enclosed in the liquid storage portion 232 by the seals 232 a, 232 b. Thus, the reagent in each of the liquid storage portions 231, 232 can be inhibited from flowing into the channel 220 or the chambers 211 to 216 before the cartridge 200 is used. When the reagent in each of the liquid storage portions 231, 232 is transferred into the chamber, the inner side portion and the outer side portion of each of the liquid storage portions 231, 232 are opened. Therefore, as compared to the structure in Embodiment 1, the reagent in each of the liquid storage portions 231, 232 can be smoothly transferred into the chamber.

Before the seal is opened, the reagent in each of the liquid storage portions 231, 232 is positioned on the outer circumferential side in advance. Thus, after the seal is opened, the reagent in each of the liquid storage portions 231, 232 can be smoothly transferred into the chamber positioned on the outer side. After the seals 231 b, 232 b on the outer side are opened, the seals 231 a, 232 a on the inner side are opened. Thus, the reagent in each of the liquid storage portions 231, 232 is not returned toward the inner side, and the reagent in each of the liquid storage portions 231, 232 can be smoothly transferred into the chamber positioned on the outer side.

Next, the pressing portion 195 of Embodiment 6 will be described.

The pressing portion 195 of Embodiment 6 includes a moving member 365 and a plurality of cam portions disposed in the moving member 365 for moving, in the pressing direction, pin members 366 for opening seals, respectively. The cam portions are disposed at different positions, respectively, in the direction in which the moving member 365 moves, in order to drive the pin members 366 in a predetermined order. Specifically, the pressing portion 195 is structured as shown in FIG. 26B to FIG. 27B.

As shown in FIG. 26B, in Embodiment 6, as compared to the structure in Embodiment 1, the two pin members 366 are disposed in the radial direction. Specifically, the mounting member 361 has two holes 361 a, and the pin members 366 and the rollers 367 are disposed at positions of the two holes 361 a, respectively. FIG. 27A illustrates a cross-section of C1-C2 shown in FIG. 26B as viewed in the D3 direction. FIG. 27B illustrates a cross-section of C3-C4 shown in FIG. 26B as viewed in the D3 direction. As shown in FIGS. 27A, 27B, the pin members 366 are mounted at positions of the two holes 361 a, respectively.

As shown in FIGS. 27A, 27B, on the lower surface side of the moving member 365, cam portions 365 b, 365 c are each formed as a plane tilted relative to the horizontal plane. The cam portion 365 b is formed at the position corresponding to the roller 367 on the D3 direction side. The cam portion 365 c is formed at the position corresponding to the roller 367 on the side opposite to the D3 direction side. The positions of the cam portions 365 b, 365 c are different from each other in the D1-D2 direction. Specifically, the cam portion 365 b is disposed on the D1 direction side as compared to the cam portion 365 c.

When the seals 231 a, 231 b of the liquid storage portion 231 are opened, the controller 301 causes the cartridge 200 to be rotated, to move the reagent in the liquid storage portion 231 toward the outer side, and thereafter causes the seals 231 a, 231 b to be positioned vertically below the pin member 366 on the side opposite to the D3 direction side, and vertically below the pin member 366 on the D3 direction side, respectively.

The controller 301 drives the motor 362 to move the moving member 365 in the D1 direction. In this case, when the moving member 365 is moved in the D1 direction in the states shown in FIGS. 27A, 27B, before the cam portion 365 c contacts with the roller 367, the cam portion 365 b contacts with the roller 367, and the cam portion 365 c thereafter contacts with the roller 367. Therefore, the pin member 366 on the D3 direction side moves downward before the pin member 366 on the side opposite to the D3 direction side moves downward. Thus, as described above, the seal 231 b on the outer side is opened earlier, and the seal 231 a on the inner side is thereafter opened.

Thus, in a case where the cam portions 365 b, 365 c different from each other are provided on the lower surface of the moving member 365, and the pin members 366 are provided so as to correspond to the cam portions 365 b, 365 c, the seals 231 b, 231 a can be opened in order, respectively, simply by moving the moving member 365 in the D1 direction. For the seals 232 a, 232 b of the liquid storage portion 232, the opening process is performed in the similar manner. Also in this case, simply by moving the moving member 365 in the D1 direction, the seals 232 b, 232 a can be opened in order, respectively. 

What is claimed is:
 1. A chemiluminescence measurement apparatus comprising: a support member configured to support a cartridge for measuring a test substance contained in a specimen by chemiluminescence measurement; a motor configured to rotate the support member so as to rotate the cartridge such that a process required for the chemiluminescence measurement proceeds in the cartridge; and a light receiver configured to receive light generated by chemiluminescence in the cartridge that is supported by the support member rotated by the motor, wherein the cartridge supported by the support member and a light receiving surface of the light receiver are disposed inside a dark space surrounded by a light-shielding portion, and the motor is disposed outside the dark space.
 2. The chemiluminescence measurement apparatus of claim 1, wherein: the cartridge comprises a liquid storage portion including a seal, the chemiluminescence measurement apparatus comprises a pressing portion configured to press the seal, and the support member is positioned so as to oppose the pressing portion across the cartridge.
 3. The chemiluminescence measurement apparatus of claim 1, comprising: a rotation shaft fixed to the support member, wherein the motor operates to rotate the rotation shaft, the light-shielding portion has a hole through which a drive shaft of the motor is joined to the rotation shaft, and the motor is mounted to an outer side surface of the light-shielding portion so as to close the hole.
 4. The chemiluminescence measurement apparatus of claim 3, wherein the support member is provided so as to extend from the rotation shaft side to a position opposing a pressing portion.
 5. The chemiluminescence measurement apparatus of claim 3, wherein: the cartridge comprises a chamber in which liquid is stored, and a channel through which the liquid in the chamber is transferred from the chamber, the chamber is connected to the channel on the rotation shaft side, and the chamber comprises protrusions that protrude toward the rotation shaft, and that are disposed on both sides which sandwich a connecting position at which the chamber connects to the channel.
 6. The chemiluminescence measurement apparatus of claim 5, wherein the chamber comprises planar wall surfaces that are connected to the protrusions, respectively, and that are disposed on both sides which sandwich the connecting position.
 7. The chemiluminescence measurement apparatus of claim 3, wherein: a chamber comprises a projection that projects toward the rotation shaft, and a channel is connected to the projection.
 8. The chemiluminescence measurement apparatus of claim 1, wherein the motor operates so as to change a rotation speed of the support member.
 9. The chemiluminescence measurement apparatus of claim 3, wherein: a light-shielding elastic member is disposed, between the outer side surface and a surface, of the motor, which opposes the outer side surface, so as to surround the hole, and the motor is mounted to the outer side surface of the light-shielding portion so as to press the surface of the motor against the elastic member.
 10. The chemiluminescence measurement apparatus of claim 1, wherein the light receiver is capable of performing photon counting.
 11. The chemiluminescence measurement apparatus of claim 1, wherein the light receiver is a photomultiplier.
 12. The chemiluminescence measurement apparatus of claim 1, wherein a light receiving unit that comprises the light receiver is disposed inside the dark space.
 13. The chemiluminescence measurement apparatus of claim 1, wherein: the cartridge comprises: a chamber in which a complex of the test substance and magnetic particles is stored; and a channel through which the complex is transferred from the chamber, and the chemiluminescence measurement apparatus further comprises a magnet for transferring the complex from the chamber through the channel.
 14. The chemiluminescence measurement apparatus of claim 13, wherein the magnet is disposed inside the dark space.
 15. The chemiluminescence measurement apparatus of claim 13, comprising: a movement mechanism configured to move the magnet relative to the cartridge in order to transfer the complex from the chamber through the channel, wherein the movement mechanism and the magnet are both disposed inside the dark space.
 16. The chemiluminescence measurement apparatus of claim 15, wherein an outline of each of the motor and an apparatus body is rectangular in a planar view, the motor is disposed such that a corner of the motor and a corner of the apparatus body are misaligned in the planar view, and a light receiving unit that comprises the light receiver is disposed in a space between the motor and the corner of the apparatus body in the planar view, and the magnet and the movement mechanism are disposed in a space between the motor and another corner of the apparatus body in the planar view.
 17. The chemiluminescence measurement apparatus of claim 1, comprising a ventilator configured to dissipate heat generated from the motor to outside of the apparatus.
 18. The chemiluminescence measurement apparatus of claim 17, wherein: a housing is formed for housing a member disposed in the dark space such that an outer side surface, on the motor side, of the light-shielding portion projects, and the motor is disposed lateral to the housing so as to form a space between the motor and the housing.
 19. The chemiluminescence measurement apparatus of claim 18, wherein the two housings are formed in the light-shielding portion so as to form a space between the two housings, the motor is disposed between the two housings, and the ventilator is disposed so as to oppose the space between the two housings.
 20. A method for measuring a test substance by using a chemiluminescence measurement apparatus, the method comprising: rotating a cartridge disposed inside a dark space of the chemiluminescence measurement apparatus by using a motor disposed outside the dark space; causing a process required for measuring the test substance by chemiluminescence measurement to proceed in the cartridge; and receiving, by a light receiver disposed inside the dark space, light generated in the cartridge by chemiluminescence, wherein the dark space is surrounded by a light-shielding portion. 